Mobile oauth service

ABSTRACT

A framework, which conforms to the OAuth standard, involves a generic OAuth authorization server that can be used by multiple resource servers in order to ensure that access to resources stored on those resource servers is limited to access to which the resource owner consents. Each resource server registers, with the OAuth authorization server, metadata for that resource server, indicating scopes that are recognized by the resource server. The OAuth authorization server refers to this metadata when requesting consent from a resource owner on behalf of a client application, so that the consent will be of an appropriate scope. The OAuth authorization server refers to this metadata when constructing an access token to provide to the client application for use in accessing the resources on the resource server. The OAuth authorization server uses this metadata to map issued access tokens to the scopes to which those access tokens grant access.

CLAIM OF PRIORITY

The present application claims priority under 35 U.S.C. §119(e) to U.S.Provisional Patent Application Ser. No. 61/880,335, filed Sep. 20, 2013,and titled “MULTIPLE RESOURCE SERVERS WITH SINGLE, FLEXIBLE, PLUGGABLEOAUTH SERVER AND OAUTH-PROTECTED RESTFUL OAUTH CONSENT MANAGEMENTSERVICE, AND MOBILE APPLICATION SINGLE SIGN ON OAUTH SERVICE,” theentire contents of which are incorporated by reference herein.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is related to U.S. Provisional PatentApplication Ser. No. 61/541,026, filed Sep. 29, 2011, and titled“RELYING PARTY AND OAUTH FRAMEWORK,” the entire contents of which areincorporated by reference herein. The present application is alsorelated to U.S. patent application Ser. No. 13/631,538, filed Sep. 28,2012, and titled “OAUTH FRAMEWORK,” the entire contents of which areincorporated by reference herein.

BACKGROUND

An identity management system is an information system, or a set oftechnologies that can be used for enterprise or cross-network identitymanagement. Identity management describes the management of individualidentities, their authentication, authorization, roles, and privilegeswithin or across system and enterprise boundaries with the goal ofincreasing security and productivity while decreasing cost, downtime,and repetitive tasks. One aspect of identity management is “singlesign-on” (SSO). One standard that is particularly useful in the field ofidentity management is OAuth.

SSO is a property of access control of multiple related but independentsoftware systems. With this property, a user logs in once and gainsaccess to all systems without being prompted to log in again at each ofthem. Conversely, single sign-off is the property whereby a singleaction of signing out terminates access to multiple software systems. Asdifferent applications and resources support different authenticationmechanisms, single sign-on internally translates to and stores differentcredentials compared to what is used for initial authentication. SSOreduces phishing success, because users are not trained to enterpasswords everywhere without thinking SSO reduces password fatigue fromdifferent user name and password combinations. SSO reduces time spentre-entering passwords for the same identity. SSO reducing informationtechnology (IT) costs due to a lower number of IT help desk calls aboutpasswords. SSO provides security on all levels of entry/exit/access tosystems without the inconvenience of re-prompting users. SSO also allowsfor centralized reporting for compliance adherence. SSO uses centralizedauthentication servers that all other applications and systems utilizefor authentication purposes, and combines this with techniques to ensurethat users do not have to actively enter their credentials more thanonce.

OAuth is an open standard for authorization. An indirect effect ofauthorization is authentication. OAuth allows users to share theirprivate resources (e.g., photos, videos, contact lists, etc.) stored onone site with another site without having to hand out their credentials,typically supplying username and password tokens instead. Each tokengrants access to a specific site for specific resources and for adefined duration. This allows a user to grant a third party site accessto their information stored with another service provider, withoutsharing their access permissions or the full extent of their data. Forexample, a token might grant access to a video editing site for videosfrom a specific album for the next two hours.

For example, in a typical scenario, a user of LinkedIn might be askedfor permission to import, into LinkedIn, that user's contacts fromYahoo. LinkedIn might want to obtain these contacts in order to sende-mail messages inviting each of the user's contacts to join LinkedIn,for example. Prior to OAuth, this request for permission might haveinvolved a request that the user provide, to LinkedIn, the user's Yahoouser identity and password. This information was requested so thatLinkedIn could log-in to the user's Yahoo account as that user, and thenobtain that user's contacts from that user's Yahoo account. Generallyspeaking, permitting LinkedIn (or any site) with the user's Yahoo (orany other site) identity and password is a bad idea because it grantsthe former site unlimited access to the user's account on the lattersite. Such unlimited access is nearly always much more access than theformer site actually requires to accomplish its goal, such as merelyobtaining a contact list.

A better idea is to provide the former site with a limited authorizationrelative to the user's account on the latter site. The limitedauthorization may specify a specific set of operations that the formersite can perform relative to the user's account on the latter site. Forexample, referring to the typical scenario above, the limitedauthorization might specify that LinkedIn can only access the user'scontact list, but perform no other operations relative to the user'saccount, on Yahoo. OAuth allows for such limited authorization. OAuthprovides delegation of authorization.

The technique by which OAuth delegates authorization may be understoodrelative to an analogy. Often, when a car owner temporarily relinquishescontrol of his car to a valet so that the valet can park the car for theowner, the owner does not provide a general-use master key to the valet,but instead provides a more limited-use valet key to the valet. Thevalet key permits the valet with sufficient access to drive the car, butdoes not provide the valet with access to everything that the ownerpossesses within the car. In the same manner, the use of OAuth may granta first site access to a user's contact list stored by a second site,without also permitting the first site to perform other operationsrelative to the user's account on the second site—such as reading e-mailmessages that might be stored on the second site, for example. OAuthallows the first site to be given a limited authorization to perform aspecified set of operations, and no others, relative to the second site.

For another example, a user might want to use a photo printing serviceprovided by a first site, such as Snapfish, to print certain colorphotos that are electronically stored on a second site, such as Flickr,which is independent of the first site. More specifically, the usermight want to print only the photos that are stored in a particularalbum on Flickr, such as an album containing photos from the user'srecent visit to Alaska. Although the user might have a multitude ofdifferent albums stored on his Flickr account, the user might want toprint only the photos from the Alaska album. Under such circumstances,the user probably prefers that Snapfish does not access the contents ofany of his Flickr albums other than those contained within the Alaskaalbum. In the foregoing scenario, using OAuth terminology, Snapfish isconsidered to be a client, and Flickr is considered to be a resourceserver (the photo data being the resources) as well as an OAuthauthorization server. As the owner of the resources (e.g., photo data)stored by the resource server, the user is also a resource owner.

Given the example presented above, the user might first use his Internetbrowser application to instruct the client (e.g., Snapfish) to print thephotos in the user's Alaska album on the resource server (e.g., Flickr).In response, the client (e.g., Snapfish) redirects the user to the siteof the resource server (e.g., Flickr). This redirection operation mayindicate, to the resource server, the limited set of data (e.g.,contents of the Alaska album) to which the client desires access. Atthat moment, the resource server does not know who the user is, as theuser has not yet authenticated himself to the resource server.Therefore, the resource server requires the user to authenticate. As ismentioned above, an indirect effect of authorization is authentication.After the user authenticates himself to the resource server (e.g., byproviding his username and password that are relevant to the resourceserver), the resource server sends a consent page to the user's Internetbrowser. The consent page asks the user to verify that the resourceserver (e.g., Flickr) has the user's permission to provide a limited,specified set of data (e.g., contents of the Alaska album) to the client(e.g., Snapfish). Assuming that the user consents, the resource serverthen responsively sends an authorization code to the client. Thisauthorization code may be sent through the “front channel;” or, in otherwords, via the user's Internet browser using a redirect.

For purposes of the following discussion, the resource server alsoserves the role of OAuth authorization server, but is referred to asbeing the resource server. In this scenario, the client (e.g., Snapfish)is a trusted partner of the resource server (e.g., Flickr). The clientreceives the authorization code, or “grant,” and stores theauthorization code. The client maintains this authorization codeindefinitely, until the user actively revokes that authorization code.The user may log-in to the OAuth authorization server in order to see alist of grants that the OAuth authorization server has provided on theuser's behalf to various clients. In response to receiving theauthorization code, the client (e.g., Snapfish) makes a “back channel”call to the resource server (e.g., Flickr). A back channel call is acommunication that does not involve the user's Internet browser. Theback channel call requests an access token from the resource server. Theaccess token specifies the scope of the access that the client ispermitted to the user's account on the resource server. For example, theaccess token might indicate that the client is permitted access only tocontents of the user's Alaska album. The resource server sends therequested access token back to the client via the back channel. Theclient stores the access token. Thereafter, until the access tokenexpires, or until the user revokes the grant (i.e., the authorizationcode), the client can present the access token to the resource server inorder to access, on the resource server, the resources specified by theaccess token. If the user has already revoked the grant related to theaccess token, then the access token becomes ineffective even if theaccess token has not yet expired.

In addition to an access token, the resource server may provide a“refresh token” to the client. While the access token often has aspecified longevity after which it expires, a refresh token is along-lived token. The client may store the refresh token along with therelated access token. Thereafter, if the resource server objects thatthe client's current access token has expired, then the client maypresent the refresh token to the resource server in order to obtain anew access token from the resource server.

Beneficially, the approach employed by OAuth avoids the disclosure, tothe client, of the user's password for the user's account on theresource server. The avoidance of this disclosure of credentialsprevents the client from performing unauthorized actions relative to theuser's account on the resource server. The only time that the usersupplies his password is during the user's initial authenticationdirectly with the resource server, after being redirected from theclient's site.

BRIEF SUMMARY

Embodiments of the present invention relate to identity management,authentication, and authorization frameworks. In one embodiment, aframework is provided for integrating Internet identities in enterpriseidentity and access management (IAM) infrastructures. According toanother embodiment, a framework is provided for open authorization.

Traditionally, a resource server and an OAuth authorization server havebeen the same entity. According to an embodiment of the invention, ageneric framework is provided that frees a resource server from theresponsibilities of an OAuth authorization server. Theseresponsibilities can include scope management, issuance of authorizationtokens, issuance of refresh tokens, and issuance of access tokens. Thus,a generic OAuth authorization server can be implemented according tothis generic framework. Consequently, each individual resource serverdoes not need to implement its own proprietary OAuth authorizationserver. Indeed, according to an embodiment of the invention, multipledifferent resource servers can all concurrently make use of thefunctions of the same generic OAuth authorization server. For example,in an embodiment of the invention, a single OAuth authorization servercan manage scopes for several different resource servers all at the sametime. There can be a many-to-one relationship between resources serversand an OAuth authorization server.

In one embodiment of the invention, in order to achieve this ability tointeract with multiple different resource servers, the generic OAuthauthorization server maintains mapping data that indicates which tokensbelong to which resource servers, who the trusted partners of eachresource server are, etc. Furthermore, in an embodiment of theinvention, the generic OAuth framework is constructed in such a mannerthat a resource server administrator can easily customize the frameworkto accommodate the particular use case for his resource server.Different resource server administrators can “plug-in” their specificcomponents into the generic OAuth framework. Thus, in one embodiment ofthe invention, each resource server informs the generic OAuthauthorization server regarding the potential scopes (i.e., limitedoperations relative to resources) that the resource server might use.

The foregoing, together with other features and embodiments will becomemore apparent upon referring to the following specification, claims, andaccompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating an OAuth system architecture andlogical components thereof, according to an embodiment of the invention.

FIG. 2 is a block diagram illustrating a resource server environment,according to an embodiment of the invention.

FIG. 3 is a block diagram illustrating an OAuth client environment,according to an embodiment of the invention.

FIG. 4 is a flow diagram that illustrates an example of a technique thatan OAuth authorization server in a multi-identity domain cloud-basedcomputing environment can use to generate authorization tokens fordifferent applications executing in the context of separate isolatedidentity domains, according to an embodiment of the invention.

FIG. 5 is a block diagram that illustrates an example of a cloud-wideOAuth authorization server that interacts with clients from separateenterprises, having different identity domains, in order to authorizethose clients relative to cloud-provided services, according to anembodiment of the invention.

FIG. 6 is a flow diagram that illustrates an example of a technique foraugmenting a token with user-specific attributes, according to anembodiment of the invention.

FIG. 7 is a flow diagram that illustrates an example of a technique forgenerating a single token usable to request services from multipleresource servers, according to an embodiment of the invention.

FIGS. 8A-B show a flow diagram that illustrates an example of atechnique for plugging in resource server-maintained authorizationpolicies to an OAuth authorization server, according to an embodiment ofthe invention.

FIG. 9 is a flow diagram that illustrates an example of a technique forrouting an authentication request to a client-specific plug-in modulethat accesses a client-specific user identity repository, according toan embodiment of the invention.

FIG. 10 is a flow diagram that illustrates an example of a technique forgenerating tokens that have identity domain-specific token attributes,according to an embodiment of the invention.

FIG. 11 is a flow diagram that illustrates an example of a technique forgenerating tokens containing token attributes having values that areoverridden by resource servers, according to an embodiment of theinvention.

FIG. 12 is a flow diagram that illustrates an example of a techniquewhereby a shared OAuth authorization server makes calls to differentregistered adaptive access managers for different identity domains in acloud computing environments, according to an embodiment of theinvention.

FIG. 13 is a flow diagram that illustrates an example of a techniquewhereby an OAuth authorization server provides a Representational StateTransfer (REST) interface for consent management, according to anembodiment of the invention.

FIG. 14 is a flow diagram that illustrates an example of a techniquewhereby a server maintains an active user session for multipleinterrelated applications that execute on a mobile device separate fromthe server, according to an embodiment of the invention.

FIG. 15 is a flow diagram that illustrates an example of a technique forsecurely sending a client registration token to a mobile device throughout-of-band channels so that the mobile device can subsequently use thatclient registration token to achieve single sign-on functionality,according to an embodiment of the invention.

FIG. 16 depicts a simplified diagram of a distributed system forimplementing one of the embodiments.

FIG. 17 is a simplified block diagram of components of a systemenvironment by which services provided by the components of anembodiment system may be offered as cloud services, in accordance withan embodiment of the present disclosure.

FIG. 18 illustrates an example of a computer system in which variousembodiments of the present invention may be implemented.

DETAILED DESCRIPTION

In the following description, for the purposes of explanation, specificdetails are set forth in order to provide a thorough understanding ofembodiments of the invention. However, it will be apparent that theinvention may be practiced without these specific details. The entirecontents of U.S. Provisional Patent Application Ser. No. 61/541,026,filed Sep. 29, 2011, and titled “RELYING PARTY AND OAUTH FRAMEWORK,” areincorporated by reference herein.

General OAuth System Architecture

FIG. 1 is a block diagram illustrating an OAuth system architecture 100and logical components thereof, according to an embodiment of theinvention. Architecture 100 includes a resource owner (or user) 102, aclient application 104, a resources registry 106, and a resourceecosystem 110. Resource ecosystem includes a clients registry 112, atoken-scope registry 114, a scope registry 116, a user consent 120, anda resource server 122. Although one resource server 122 is shown,embodiments of the invention can include multiple separate resourceservers. As seen from the connections in FIG. 1, client application 104interacts with resources registry 106. Resource owner 102 interacts withresources registry 106 and with clients registry 112. Authorizationserver 118 interacts with clients registry 112, token-scope registry114, and user consent 120. Resource server 122 interacts withtoken-scope registry 114. User consent 120 interacts with scope registry116. These components and their functions are discussed further below.

Embodiments of the invention can involve the delegation ofauthorization. Different resource use cases sometimes require differentscope definitions. Different resources sometimes can rely on differentauthorization models and solutions. Different specific user actions canbe required to give a client application consent to access resourcesmaintained by different resource servers. Preferably, each differentresource provider should not need to offer a separate proprietary OAuthauthorization server to integrate with the specifics of that resourceprovider. The unfortunate result of each resource provider offering aseparate proprietary OAuth authorization server would be that anenterprise wishing to integrate with multiple different resourceproviders and multiple different client form factors will have to dealwith a myriad of different OAuth authorization server interfaces.

Therefore, in an embodiment of the invention, a generic OAuth frameworkarchitecture is provided. The framework can include OAuth wire protocolcomponents (client and server), including metadata and runtimeregistries. The framework can include an infrastructure of pluggable“contracts” to customize and deploy application-specific solutions.

In one embodiment of the invention, resource server 122 stores, intoken-scope registry 114, indications of the scopes that resource server122 recognizes. Each such scope can be indicative of a different set ofoperations that can be performed relative to a different set ofresources stored on resource server 122. Inasmuch as certain embodimentsmay include multiple different or separate resource servers, token-scoperegistry 114 can store mapping between different resource servers anddifferent scopes. Furthermore, in one embodiment of the invention, eachscope is mapped to a separate token within token-scope registry 114.Thus, by reference to token-scope registry 114, resource server 122 candetermine the set of operations and the set of resources that are mappedto a particular token presented to resource server 122 by clientapplication 104. Resource server 122 can limit the operations performedby client application 104 relative to resources maintained by resourceserver 122 to those operations specifically indicated by the set ofoperations mapped to the particular token.

Thus, in one embodiment of the invention, each particular resourceserver in a group of multiple resource servers provides, to the OAuthframework, a different set of metadata that indicates the scopes thatcan be mapped to tokens that can be used to access resources on thatparticular resource server. The scopes are therefore customizable by theadministrators of the resource servers, making the OAuth frameworkflexible and applicable to many different use cases. Consequently, manydifferent types of resource servers can all make use of the same genericOAuth framework without requiring the creation of a specific OAuthframework for each different type of resource server.

In an embodiment, the generic OAuth framework shown in FIG. 1 provides abasic conceptual structure. The OAuth framework can layer on top ofexisting identity management products. In the OAuth framework, contractscan define integration points with these existing products. Thecombination of the OAuth framework and contract implementations canfulfill miscellaneous use cases and deployment options. According to anembodiment, the OAuth framework includes two broad “roles”: aconsumer/client role, and an authorization server/resource server role.The authorization server/resource server role is discussed below withreference to FIG. 2, while the consumer/client role is discussed belowwith reference to FIG. 3.

FIG. 2 is a block diagram illustrating a resource server environment200, according to an embodiment of the invention. In an embodiment ofthe invention, environment 200 includes resource owner (or user) 202,client application 204, resource server 210, OAuth authorization server220, policy service 240, and token service 250. Resource server 210includes resource server application 212, which includes access tokenvalidation API 214 and gate 216. OAuth authorization server 220 includestoken-scope registry 222, resources & scope registry 224, user consentorchestration 226, OPSS-TS (Oracle Platform Security Services-TS) 228,OPSS-AZ (Oracle Platform Security Services-AZ) 230, OAuth core engine232, OAuth protocol engine 234, and client registry 236. In anembodiment, resource owner 202 interacts with client application 204through gate 216, which accesses access token validation API 214. Clientapplication 204 also interacts with OAuth authorization server 220.Access token validation API 214 interacts with token-scope registry 222and with policy service 240. OPSS-TS interacts with token service 250.OPSS-AZ interacts with policy service 250. Components 228-234collectively interact with token-scope registry 222 and with userconsent orchestration 226. User consent orchestration 226 interacts withresources & scope registry 224.

In an embodiment of the invention, resources & scope registry 224 storesresource information, scopes, and miscellaneous metadata related toresources and services exposed via OAuth authorization server 220. In anembodiment of the invention, client registry 236 stores trust keys andsecrets for authorized remote clients (e.g., client application 204). Inan embodiment, token-scope registry 222 stores access tokens and refreshtokens that are issued to clients (e.g., client application 204) basedon user (e.g., resource owner 202) consent. In an embodiment,token-scope registry 222 stores AuthZ scope information that isassociated with issued access tokens.

In an embodiment of the invention, resource server 210 registers its ownmetadata with OAuth authorization server 220. Different resource serverscan register different metadata with the same OAuth authorizationserver. As part of the registration process, this metadata is importedinto OAuth authorization server 220. The metadata indicates the variousdifferent scopes recognized by, or exposed by, resource server 210. Eachscope specifies a different subset of the resources maintained byresource server 210. In an embodiment of the invention, at the time ofregistration, each scope recognized by resource server 210 is mapped toresource server 210 (only) in resources & scope registry 224. Thus, inan embodiment of the invention, resources & scope registry indicates,for each registered scope, the set of the corresponding resourceserver's resources that are accessible within that scope. A scope mightindicate, for example, that only a particular photo is accessible, orthat a particular folder of photos is accessible, or that a particularset of folders is accessible. A scope can indicate operations that arepermissible relative to specified resources, such as read, update,delete, create, etc.

In an embodiment of the invention, OAuth authorization server 220 issuesaccess tokens to client application 204. In an embodiment, for each suchaccess token, OAuth authorization server 220 stores, in token-scoperegistry 222, a mapping between that access token and the particularscope (selected from among the scopes stored in resources & scoperegistry 224) that is assigned to that access token. Different accesstokens for the same resource server may have different scopes assignedto them. Thus, when client application 204 presents an access token toOAuth authorization server 220, OAuth authorization server 220 may referto token-scope registry 222 to determine the scope that is mapped tothat access token, and then may refer to resources & scope registry 224to determine the resources that are accessible within that scope.

In an embodiment of the invention, user consent from resource owner 202is required in order for OAuth authorization server 220 to grant anaccess token to client application 204. For example, if clientapplication 204 requests access to a particular resource (or aparticular scope including that resource) from resource server 210, thenresource server 210 may redirect the request to OAuth authorizationserver 220. OAuth authorization server 220 may invoke user consentorchestration 226 in order to ask resource owner 202 to verify thatclient application 204 should be granted access to the particularresource (or particular scope). In an embodiment, user consentorchestration 226 indicates, to resource owner 202, the scope to whichclient application 204 is seeking access, and provides resource owner202 with the opportunity to consent to or decline access of that scope.More specifically, OAuth authorization server 220 may ask resource owner220 to verify that client application 204 should be granted accessspecified by the particular scope (as indicated in resources & scopesregistry 224), including the particular resource. In response toreceiving consent from resource owner 202, OAuth authorization server220 may generate an access token and store, in token-scope registry 222,a mapping between that access token and the particular scope. OAuthauthorization server 220 can provide the access token to clientapplication 204.

Client application 204 can then attempt to access the particularresource on resource server 210 by presenting the access token toresource server application 212. An agent on resource application server212 can intercept the token and validate the token with OAuthauthorization server 220 (e.g., via access token validation API 214)before allowing client application 204 to access the particularresource. If the particular resource that client application 204attempts to access does not fall within the scope that is mapped theaccess token in token-scope registry 222 (e.g., if client application204 attempts to access a folder that is outside of the scope of accessto which resource owner 202 previously consented), then OAuthauthorization server 220 will not validate the token, and resourceserver 210 will refuse to grant client application 204 access to theparticular resource. Thus, scope of access is based on specific consentto that scope by resource owner 202. Resource owner 202 has theopportunity to refuse to give consent to a specific scope requested byclient application 204, in which case OAuth authorization server 220will not create an access token for client application 204. In oneembodiment of the invention, each client application's request to accessa resource maintained by resource server 210 also specifies a scope thatis mapped to resource server 210 in resources & scope registry 224, andit is this specified scope for which the consent of resource owner 202is requested as discussed above.

According to an embodiment of the invention, consistent with thediscussion above, enforcement of access restrictions occurs at the timethat client application 204 presents an access token to resource server210. Enforcement requires an understanding of the scope that is encodedby the access token. Access tokens are issued by OAuth authorizationserver 220 per the scope definitions. Access tokens are validated perthe scope that is encoded by the issued tokens. In one embodiment of theinvention, policy service 240 and token service 250 in combinationmaintain the state of the access tokens that were issued and authorizeissued access tokens. In an embodiment of the invention, a customer(i.e., owner and/or operator of resource server 210) can provide its ownpolicy service 240 and token service 250. The OAuth framework mayprovide programmatic contracts, or programmatic interfaces, by whichsuch customers can plug their own policy and token services into theOAuth framework in a manner that matches the scopes that those customersdefine. Each customer may publish its own set of scopes. The publishedset of scopes may indicate the form of the data that the customer'stoken service will return. The OAuth framework additionally may provide,to such customers, programming contracts or programmatic interfaces thatpermit policies to be created at the time of token issuance. Theseprogrammatic contracts or programmatic interfaces allow customers toplug their own custom programmatic code into the OAuth framework. Usingthese programmatic interfaces, a customer can wire its existinginfrastructure into the OAuth system. In an embodiment, a customer thatpublishes its set of scopes is responsible for ensuring that its tokenand/or policy services return tokens that include scope information thatis consistent with the published scopes. In response to clientapplication 204 attempting to use a token, OAuth authorization server220 can invoke an application programming interface (API) that will lookup the customer's policy and validate that token.

In an embodiment, the OAuth framework specifies the interfaces that thecustomer's code (e.g., the code for token service 250 and policy service240) needs to implement in order to interface with OAuth authorizationserver 220. The interfaces may be published so that customers are awareof the parameters that each interface expects to receive and the valuesthat each interface expects to return. When client application 204 makesa request of OAuth authorization server 220, OAuth authorization server220 makes responsive calls to the APIs related to that request. Thesecalls may involve calls to customer-coded components that generateaccess tokens and provide those access tokens to client application 204,for example. In one embodiment of the invention, OAuth authorizationservice 220 exposes the aforementioned programmatic contracts orprogrammatic interfaces in the form of OPSS-TS 228 and OPSS-AZ 230. Thecustomer's own implementation of token service 250 can interface withOPSS-TS 228, while the customer's own implementation of policy service240 can interface with OPSS-AZ 230. OAuth authorization server 220 mayinvoke separate APIs for access token creation and access tokenvalidation. The customer may implement custom programmatic code toperform each task. During validation, policies constructed during tokencreation can be accessed to determine whether the action that clientapplication 204 seeks to perform relative to resources matches thepolicy that is encoded by the access token that client application 204presents.

Additionally, in one embodiment of the invention, the customer's ownimplementation of user consent orchestration 226, which is invoked whenclient application 204 seeks an access token from OAuth authorizationserver 220, can be plugged into OAuth authorization server 220.Interfaces to resources & scope registry 224 and token-scope registry222 may be provided to the customer so that the customer can design itsimplementation of user consent orchestration 226 to obtain data fromcomponents 222 and 224 for use in constructing the consent request.

In an embodiment of the invention, the mappings stored in resources &scope registry 224 indicate not only the subsets of resources that areincluded within each scope, but also the exclusive subsets of operationsthat are permitted to be performed by client application relative tothose subsets of resources. For example, a particular mapping mayindicate for a particular scope that read and update operations, but notcreate or delete operations, can be performed relative to a specifiedsubset of resources (e.g., files, folders, directories, lists, profiles,images, documents, etc.) maintained on resource server 210. Thus, in oneembodiment of the invention, the consent request discussed abovespecifies not only a subset of resources that are associated with ascope, but also a subset of operations that are associated with thatscope. Consequently, resource owner 202 knows precisely the kinds ofoperations that he is giving consent for client application 204 toperform relative to the subset of resources within theconsent-request-specified scope.

According to an embodiment of the invention, client application 204requests resource access equivalent to one of the specific scopes thatresource server 210 has registered with OAuth authorization server 220.Thus, in one embodiment of the invention, client application 204 isdesigned with an awareness of the specific scopes that will beregistered for resource server 210. Because client application 204 mayinteract with resources maintained by a variety of different resourceservers, the vendors of various resource servers may agree upon astandard set of scopes that their resource servers will register withOAuth authorization server 220, thereby easing the design task of thedesigners of client application 204 and other client applications.

In one embodiment of the invention, a client framework is provided inorder to allow client applications, such as client application 204, toimplement “hooks” for various different types of resource providers. Forexample, client application 204 might implement separate hooks forGoogle, Facebook, Yahoo, LinkedIn, etc. FIG. 3 is a block diagramillustrating an OAuth client environment 300, according to an embodimentof the invention. OAuth client environment 300 includes a resource owner302, a resource server 304, an OAuth authorization server 306, a clientapplication 308, and an OAuth client 320. Client application 308includes an OAuth client API 310. OAuth client 320 includes an OAuthclient engine 322, a resource registry 324, a local application registry326, and a token registry 328. Resource server 304 and OAuthauthorization server 306 interact with each other. Resource server 304and OAuth client 320 interact with each other. OAuth authorizationserver 306 and OAuth client 320 interact with each other via resourceowner 302 (e.g., through redirection accomplished by an Internet browserof resource owner 302). Resource owner 302 also interacts with clientapplication 308. Client application 308 interacts with OAuth clientengine 322 through OAuth client API 310. OAuth client engine 322interacts with resource registry 324, local application registry 326,and token registry 328.

According to an embodiment of the invention, metadata regarding all ofthe different types of resource servers with which client application308 may interact are stored within resource registry 324, enablingclient application 308 to interact with a variety of different resourceservers. Resource registry can indicate, for example, the different setsof scopes recognized by each different type of resource server.Consequently, client application 308 is able to request accesscorresponding to a particular scope recognized by resource server 304,and this particular scope may be specified in the consent request thatOAuth authorization server 306 sends to resource owner 302 on behalf ofclient application 308. Resource providers can publish their OAuthstandard-compliant scope specifications so that designers can populateresource registry 308 with the appropriate server-to-scope mappings forthose providers' resource servers. In an embodiment, because resourceregistry 308 can be populated independently of client application 308,client application 308 does not need to be revised in order to interactwith newly discovered resource servers; instead, developers can simply“plug-in” the new mappings for those resource servers into resourceregistry 324, with which client application 308 interacts.

Often, a complex website that acts as a resource provider or server isnot a monolithic application. Often, instead, a complex websiteconstitutes a variety of different applications. In an embodiment of theinvention, local application registry 326 stores mappings betweenvarious different resource providers and the sets of applications thatare offered or exposed by those resource providers. Each suchapplication may be mapped in local application registry 326 to aseparate Uniform Resource Locator (URL) for that application. In oneembodiment of the invention, local application registry 326 stores trustkeys to exercise the OAuth client role to access remote resources.

Typically, client application 308 is able to use a particular accesstoken multiple times to access resources maintained by resource server304 before that particular access token expires. In an embodiment of theinvention, the access tokens that client application 308 obtains fromOAuth authorization server 306 are stored within token registry 328.Inasmuch as client application 308 may interact with multiple differentresource servers, token registry 328 can maintain mappings betweenaccess tokens and the different resource servers to which those accesstokens pertain. Token registry 328 can store both access tokens andrefresh tokens for various different remote resource servers (e.g.,resource server 304) and scopes.

Multiple Resource Servers Interacting with Single OAuth Server

Embodiments of the invention include a framework that binds clientapplications to resource servers, thereby indicating whether variousclient applications are permitted to access various resource servers. Aclient application can make a pre-authorization request to an OAuthauthorization server. The request can indicate that the client needs toaccess some specified resources. The client application can communicatewith the OAuth authorization server to request a token that the clientapplication can subsequently present to a resource server so that theresource server will allow the client application access to a resourcestored on or provided by the resource server. The foregoing operationsare performed on behalf of a human user.

Thus, a human user can attempt to perform an operation that requires aclient application to access a resource server. Prior to accessing theresource server, the client application will communicate with the OAuthauthorization server to ask the OAuth authorization server for a tokenso that the client application can access a resource that is stored onor provided by the resource server. According to an embodiment of theinvention, the OAuth authorization server is a framework thatexternalizes the acquisition of such tokens.

A cloud-based computing environment can include many different services.For example, the environment can include a storage service, a messagingservice, and other services. Each service can be provided by a separateresource server within the environment. A user might want to accesscertain of the user's resources that are maintained by a storageservice, for example. The user may instruct a client application toaccess those resources on the user's behalf. In order to access theresources, the client application may need to first acquire a token thatentitles the client application to read or write to the user's resourceson the storage resource server that provides the storage service.According to an embodiment of the invention, the OAuth authorizationserver does not unilaterally make decisions as to whether such a tokenshould or should not be granted. Instead, the OAuth authorization serverexternalizes those decisions to various authorization policy enginesthat are administered by resource servers that are external to the OAuthauthorization server. Thus, the decision as to whether a token should orshould not be granted, and the decision as to the scope of thepermissions indicated by that token, can be decided by the resourceserver that provides the service to which the client application seeksaccess. In the case of a storage service, then, in response to theclient application's request for a token, the OAuth authorization servercan relay that request to the storage resource server that provides thatstorage service. The OAuth authorization server can relay differenttoken requests to different resource servers, depending on the serviceto which access is sought.

Each service provided within the cloud computing environment can beassociated with a potentially different service administrator. Serviceadministrators can be users who are associated with the serviceadministrator role for various services within a specific identitydomain. An identity domain is a logical partition of a shared computingenvironment, such as a cloud computing environment. Such a logicalpartition can be one of several logical partitions that are isolatedfrom each other by identity domain management software that executes onthe hardware within the computing environment. Each such domain can beviewed as a “slice” of the shared hardware and software resources withinthe computing environment that is associated with a potentiallydifferent customer (who may pay for the privilege of using that slice).Each identity domain can include user identities and instances ofapplication software services—sometimes separate executing instances ofthe same software code. The identity domain management software canenforce isolation between identity domains by preventing users from onesuch domain from accessing the service instances that are not associatedwith that domain, and by preventing service instances that areassociated with one such domain from accessing user identities that areassociated with that domain.

One user can be a service administrator for one service, while anotheruser can be a service administrator for another service. Each servicecan have a set of associated authorization policies that are specific tothat service. A service's authorization policies can be administered andconfigured by the service administrator for that service. A service'sauthorization policies can indicate which users, or which user roles,are permitted to access various resources that the service provides. Forexample, a particular authorization policy for a particular storageservice can indicate that a particular user is permitted to access aparticular file that is provided by that particular storage service. Foranother example, an authorization policy can indicate different quotalimits for different types of subscribers, such as gold-levelsubscribers and platinum-level subscribers.

According to an embodiment, in response to receiving a clientapplication's request for a token, the OAuth authorization server caninvoke a policy engine that is maintained by the resource server thatprovides the service. The policy engine is administered by the service'sservice administrator. The policy engine determines whether the requestfor the token is valid, and informs the OAuth authorization server. Ifthe policy engine informs the OAuth authorization server that therequest for the token is valid, then the OAuth authorization server willresponsively return a token to the client application. Thus, the OAuthserver acts as a framework.

According to an embodiment of the invention, the cloud computingenvironment in which the OAuth authorization server is located containsmultiple separate identity domains that are isolated from each other.Each such identity domain can be associated with a separate tenant, orcustomer, such as a different business organization. Thus, a firstbusiness organization might be a first tenant that has exclusive accessto a first identity domain in the cloud computing environment, and asecond business organization might be a second tenant that has exclusiveaccess to a second identity domain in the cloud computing environment.In spite of this partitioning of the cloud computing environment intoisolated identity domains devoted to separate tenants, in one embodimentof the invention, all of the identity domains utilize a single OAuthauthorization server instance for the cloud computing environment as awhole. This advantageously avoids the need to provision a separate OAuthauthorization server for each separate identity domain. Furtherinformation about a multi-identity domain cloud computing environmentcan be found in U.S. patent application Ser. No. 13/838,813, filed onMar. 15, 2013, and titled “MULTI-TENANCY IDENTITY MANAGEMENT SYSTEM”;and also in U.S. patent application Ser. No. 14/019,051, filed on Sep.5, 2013, and titled “LDAP-BASED MULTI-TENANT IN-CLOUD IDENTITYMANAGEMENT SYSTEM.” The entire contents of U.S. patent application Ser.No. 13/838,813 and U.S. patent application Ser. No. 14/019,051 areincorporated by reference herein for all purposes.

Thus, according to an embodiment, client applications are located withindistinct identity domains that are isolated from each other.Nevertheless, each client application, when seeking a token for thepurposes of accessing a service, applies to the same cloud-wide OAuthauthorization server instance for that token. The OAuth authorizationserver, in turn, relays the token requests to the various resourceservers that provide the services to which those tokens pertain. Theresource servers maintain the authorization policies that regulate thegranting and generation of tokens for the services that those resourceservers provide. Each resource server's set of authorization policiesmay differ from each other resource server's set of authorizationpolicies. The authorization policies for one tenant may differ from theauthorization policies for another tenant, even for the same service.Thus, in one embodiment, each multi-tenant-aware resource server canmaintain multiple different sets of authorization policies, eachpertaining to a separate identity domain that is devoted to a differenttenant.

In one embodiment of the invention, the single cloud-wide OAuthauthorization server maintains a separate virtualized “slice” of OAuthauthorization server for each separate identity domain into which thecloud computing environment has been partitioned. For each such “slice,”the OAuth authorization server can store separate configurationdata—called an OAuth service profile—that pertains to the identitydomain to which that slice is dedicated. Thus, the OAuth service profilethat the OAuth authorization server stores for one identity domain candiffer from the OAuth service profile that the OAuth authorizationserver stores for another identity domain. From the perspective of thevarious different tenants who are served by the cloud computingenvironment, the OAuth authorization server acts only on their behalf,and not on the behalf of any other tenants—this only appears to be thecase to the tenants, however. The tenants are insulated from the factthat the OAuth authorization server maintains separate OAuth serviceprofiles for separate identity domains. The multi-identity domain natureof the OAuth authorization server is obscured from the tenants who ownthose identity domains. Each tenant's client applications can interactwith the OAuth authorization server in the multi-identity domain cloudcomputing environment in a manner that is similar to that in which thoseclient applications would have interacted with an OAuth authorizationserver in a single identity domain enterprise environment implemented onthat tenant's own computing machinery. The various client applicationsdo not need to be modified to be made operable with the multi-tenantOAuth authorization server.

Thus, in an embodiment of the invention, the OAuth authorization servermaintains a mapping between various identity domains and the OAuthservice profiles for those identity domains. The OAuth authorizationserver as enhanced applies not just to a specific enterpriseenvironment, but to an entire cloud computing environment that ispartitioned into separate isolated identity domains. Client applicationsfrom various different identity domains can all use the same or similardestinations, or endpoints, to access the same OAuth authorizationserver. Such destinations can take the form of URLs, for example. Clientapplications do not need to be configured to use separate URLs forseparate OAuth authorization servers. In one embodiment, the URLs thateach identity domain's client applications use to access the singlecloud-wide OAuth authorization server have the same suffix, butdifferent prefixes that identify that identity domain. The OAuthauthorization server can use this identity domain prefix in order todetermine which particular OAuth service profile, from the multiple setsof OAuth service profiles that the server maintains, applies to aparticular client application from which the OAuth authorization serverreceives a token request.

In an embodiment, the single cloud-wide multi-tenant OAuth authorizationserver still relays token requests to resource servers that provide theservices to which those requests pertain. Those resource servers, andnot the OAuth authorization server, maintain the authorization policiesthat govern the services that those resources servers provide. Suchpolicies can indicate the various levels of resource access (e.g., readquotas, write quotas, delete quotas, etc.) that should be granted tovarious different user roles. Resource servers can be dedicated tospecific identity domains, in which case they can maintain authorizationpolicies applicable only to a single identity domain, or resourceservers can be multi-tenant-aware servers that maintain separate sets ofauthorization policies that are applicable to different identitydomains.

As is discussed above, in an embodiment of the invention, a single OAuthauthorization server maintains multiple separate OAuth serviceprofiles—one per identity domain. In an embodiment of the invention, theOAuth service profile for a particular identity domain binds clientapplications to resource servers, thereby indicating, for each clientapplication, the resource servers that the client application ispermitted to access; some client applications might not be permitted toaccess some resources servers. Such application-to-server bindingsspecified within one OAuth service profile data might differ fromapplication-to-server bindings specified within another OAuth serviceprofile, so that separate instances of a particular client applicationexecuting in the context of different identity domains might not haveaccess to the same resource servers.

According to one embodiment, multiple separate OAuth service profilescan be generated and associated with a same identity domain. Forexample, a human resources (HR) OAuth service profile might indicatethat HR client applications are permitted to access only HR resourceservers in a particular tenant's identity domain, while a marketingOAuth service profile might indicate that marketing client applicationsare permitted to access only marketing resource servers in that sameparticular tenant's identity domain.

In an embodiment, the cloud-wide OAuth authorization server consults thebindings specified within a particular OAuth service profile in responseto receiving a token request from a client application. For example, theOAuth authorization server can consult the bindings specified with theOAuth service profile that is associated with the identity domain inwhich the client application executes. Based on the bindings, the OAuthauthorization server determines whether that client application is evenallowed to communicate with the resource server to which the requestedtoken pertains. If the particular OAuth service profile indicates thatthe client application is not bound to the resource server, then theclient application's request is denied without any interaction with theresource server.

Alternatively, if the particular OAuth service profile indicates thatthe client application is bound to the resource server, then the OAuthauthorization server determines, from the particular OAuth serviceprofile, a callback URL for the resource server. The OAuth authorizationserver uses this URL to send, to the resource server, an inquiryregarding the scope of access (e.g., quotas) that the client applicationand/or user is permitted to have relative to the requested resource. Inresponse to such an inquiry, the resource server can determine, byapplying its authorization policies to the parameters of the request(e.g., client application identity, user identity, resource identity),the scope of access that should be granted, if any. The resource servercan reply to the OAuth authorization server with this scope of accessinformation. Alternatively, the OAuth authorization server can obtainthe resource server's authorization policies from the resource server,store a copy locally, and can apply those policies itself to determinethe scope of access that should be granted. The OAuth authorizationserver can generate an appropriate token based on the scope of accessinformation determined, and can provide this token to the clientapplication in response to the client application's token request. Theclient application can thereafter present the token to the resourceserver when seeking access to services that the resource serverprovides. The resource server can restrict the client application'saccess to its services based on the scope of access informationcontained within the token.

FIG. 4 is a flow diagram that illustrates an example of a technique thatan OAuth authorization server in a multi-identity domain cloud-basedcomputing environment can use to generate authorization tokens fordifferent applications executing in the context of separate isolatedidentity domains, according to an embodiment of the invention. In block402, an OAuth authorization server receives a request from a firstclient application that executes in a context of a first identity domainof a plurality of isolated identity domains. In block 404, the OAuthauthorization server selects, from a plurality of OAuth service profilesthat the OAuth authorization server maintains, a first OAuth serviceprofile that is applicable only to the first identity domain. In block406, the OAuth authorization server determines, based on the first OAuthservice profile, whether the first client application is permitted toaccess a first resource server. In block 408, the OAuth authorizationserver generates, in response to determining that the first clientapplication is permitted to access the first resource server, a firsttoken for the first client application based on scope information thatthe OAuth authorization server obtains from the first resource server.In block 410, the OAuth authorization server receives a request from asecond client application that executes in a context of a secondidentity domain of the plurality of isolated identity domains. Thesecond identity domain is separate from the first identity domain. Inblock 412, the OAuth authorization server selects, from the plurality ofOAuth service profiles that the OAuth authorization server maintains, asecond OAuth service profile that is applicable only to the secondidentity domain. In block 414, the OAuth authorization serverdetermines, based on the second OAuth service profile, whether thesecond client application is permitted to access a second resourceserver. In block 416, the OAuth authorization server generates, inresponse to determining that the second client application is permittedto access the second resource server, a second token for the secondclient application based on scope information that the OAuthauthorization server obtains from the second resource server.

FIG. 5 is a block diagram that illustrates an example of a cloud-wideOAuth authorization server that interacts with clients from separateenterprises, having different identity domains, in order to authorizethose clients relative to cloud-provided services, according to anembodiment of the invention. FIG. 5 shows separate enterprises 510A and510B. Enterprises 510A and 510B can be different and unrelated businessorganizations. Each of enterprises 510A and 510B can be a separatecustomer of the cloud computing service discussed herein. Enterprise510A includes multiple clients, such as clients 512AA and clients 512AB.Clients 512AA and 512AB can be associated with and operated by differentusers within enterprise 510A. Each of these users can have a separateidentity that is contained within an identity domain that is uniquelyassociated with enterprise 510A. Each of these users can be associatedwith a separate defined role in a hierarchy of defined roles that can beunique to enterprise 510A. Enterprise 510B also includes multipleclients, such as clients 512BA and clients 512BB. Clients 512BA and512BB can be associated with and operated by different users withinenterprise 510B. Each of these users can have a separate identity thatis contained within an identity domain that is uniquely associated withenterprise 510B. Each of these users can be associated with a separatedefined role in a hierarchy of defined roles that can be unique toenterprise 510B.

Clients 512AA, 512AB, 512BA, and 512BB each can interact with acloud-wide OAuth authorization server 502 that serves all clients of thecloud computing environment regardless of the enterprises or identitydomains to which those clients belong. Each of clients 512AA, 512AB,512BA, and 512BB can send, through Internet 514, to cloud-wide OAuthserver 502, an authorization token request that specifies (a)credentials for the user of that client, and (b) a cloud-based servicethat the client desires to access. Cloud-wide OAuth authorization server502 receives such authorization token requests through Internet 514. Foreach such authorization token request, Cloud-wide OAuth authorizationserver 502 can determine an identity domain that is associated with theclient from which that authorization token request originated. Forexample, cloud-wide OAuth authorization server 502 can determine, basedon stored mapping data, that clients 512AA and 512AB (and theirassociated users) belong to enterprise 510A and therefore to a firstidentity domain that corresponds uniquely to enterprise 510A. Continuingthe example, cloud-wide OAuth authorization server 502 can determine,based on stored mapping data, that clients 512BA and 512BB (and theirassociated users) belong to enterprise 510B and therefore to a secondidentity domain that corresponds uniquely to enterprise 510B.

In an embodiment, cloud-wide OAuth authorization server 502 storesmultiple different domain service profiles, such as domain serviceprofile 504A and domain service profile 504B. Each such domain serviceprofile can be uniquely associated with a separate identity domain. Upondetermining the particular identity domain to which a particular client(and its associated user) belongs, cloud-wide OAuth authorization server502 can determine which of several separate domain service profilesstored by server 502 corresponds uniquely to that particular identitydomain. For example, in response to determining that clients 512AA and512AB are associated with a first identity domain (e.g., that owned byenterprise 510A), cloud-wide OAuth authorization server 502 candetermine that domain service profile 504A, which is associated uniquelywith the first identity domain, is to be used to process authorizationtoken requests originating from clients 512AA and 512AB. For example, inresponse to determining that clients 512BA and 512BB are associated witha second identity domain (e.g., that owned by enterprise 510B),cloud-wide OAuth authorization server 502 can determine that domainservice profile 504B, which is associated uniquely with the firstidentity domain, is to be used to process authorization token requestsoriginating from clients 512AA and 512AB.

In an embodiment, each of domain service profiles 504A and 504B containsa separate set of client-to-service bindings. Each client-to-servicebinding can specify whether a particular client has any access (of anyscope) to a particular service (provided by a particular resourceserver). For example, domain service profile 504A can containclient-to-service bindings 506AA and 506AB, while domain service profile504B can contain client-to-service bindings 506BA and 506BB. In thisexample, client-to-service binding 506AA indicates that client 512AA isallowed to access a service provided by resource server 516A;client-to-service binding 506AA indicates that client 512AB is allowedto access a service provided by resource server 516B; client-to-servicebinding 506BA indicates that client 512BA is allowed to access a serviceprovided by resource server 516A; and client-to-service binding 506AAindicates that client 512AB is allowed to access a service provided byresource server 516B.

In one embodiment, the absence of a binding between a particular clientand a particular service is conclusive evidence that the particularclient is not permitted to access the particular service at all, whilein another embodiment, a binding can expressly specify whether or notthe particular client is permitted to access the particular service. Inan embodiment, in response to determining that a particular client isnot permitted to access the service specified within the particularclient's authorization token request, cloud-wide OAuth authorizationserver 502 can return, to the particular client, through Internet 514,an indication that the authorization token request is denied. In oneembodiment, client-to-service bindings are created in response to atenant (such as enterprises 510A and 510B) purchasing a subscription tothe services specified in those bindings and subsequently having thoseservices provisioned to that tenant's identity domain. Thus, in such anembodiment, if a particular tenant has not purchased or otherwiseobtained a subscription to a particular service, then there will be noclient-to-service bindings between that particular tenant's clients (orusers thereof) and that particular service.

In an embodiment, cloud-wide OAuth authorization server 502 additionallystores a separate service callback URL for each resource server thatprovides a service in the cloud computing environment. In the exampleillustrated, cloud-wide OAuth authorization server 502 stores servicecallback URL 508A for resource server 516A and service callback URL 508Bfor resource server 516B. In response to locating, in the domain serviceprofile for the identity domain to which a particular client belongs, aparticular client-to-service binding that specifies both the client (oruser thereof) and the service specified within an authorization tokenrequest, cloud-wide OAuth authorization server 502 determines theservice callback URL for the particular resource server that providesthat service. Cloud-wide OAuth authorization server 502 then forwardsthe authorization token request over Internet 514 to the resource serverhaving that service callback URL. Domain name servers and routers withinInternet 514 use the service callback URL to route the authorizationtoken request to the proper resource server within the cloud computingenvironment.

In an embodiment, each of resource servers 516A and 516B contains orexecutes a policy engine. For example, resource server 516A can executepolicy engine 518A, while resource server 516B can execute policy engine518B. Each of policy engines 518A and 518B can be a separate executinginstance of the same policy engine code. Each of policy engines 518A and518B can contain or can access multiple sets of policies. Each set ofpolicies can pertain to a separate identity domain. For example, policyengine 518A can access policies 520AA, which pertain to the firstidentity domain (i.e., of enterprise 510A) and/or policies 520AB, whichpertain to the second identity domain (i.e., of enterprise 510B).Similarly, policy engine 518B can access policies 520BA, which pertainto the first identity domain (i.e., of enterprise 510A) and/or policies520BB, which pertain to the second identity domain (i.e., of enterprise510B). The policies for each resource server can differ from each other.The policies for different identity domains can differ from each othereven relative to the same resource server. Thus, the policies governingclients 512AA and 512AB relative to resource server 516A can differ fromthe policies governing clients 512BA and 512BB relative to resourceserver 516A. Likewise, the policies governing clients 512AA and 512ABrelative to resource server 516B can differ from the policies governingclients 512BA and 512BB relative to resource server 516B.

In response to receiving an authorization token request that cloud-wideOAuth authorization server 502 forwarded through Internet 514, therecipient resource server can invoke its policy engine to determine aparticular set of policies that applies to the identity domain of theparticular client (or user) specified in that authorization tokenrequest. For example, in response to receiving an authorization tokenrequest specifying client 512AA or client 512AB, policy engine 518A candetermine that policies 520AA pertain to that authorization tokenrequest. In response to receiving an authorization token requestspecifying client 512BA or client 512BB, policy engine 518A candetermine that policies 520AB pertain to that authorization tokenrequest. Continuing the example, in response to receiving anauthorization token request specifying client 512AA or client 512AB,policy engine 518B can determine that policies 520BA pertain to thatauthorization token request. In response to receiving an authorizationtoken request specifying client 512BA or client 512BB, policy engine520B can determine that policies 520BB pertain to that authorizationtoken request.

In an embodiment, a particular policy engine has access to the useridentity store of each tenant that subscribes to a service that isprovided by the resource server that executes that particular policyengine. Thus, the policy engine can obtain, from the user identitystore, the attributes of the client or user specified in theauthorization token request. The policy engine can then select, from theset of policies determined to be pertinent to the authorization tokenrequest, policies that are applicable to the service specified in theauthorization token request. These selected policies can specify variousscopes of access relative to various client or user attributes. Thepolicy engine can evaluate the selected policies relative to theattributes that are associated with the identity read from the useridentity store. As a result of the evaluation, the policy engine candetermine a scope of access (e.g., which operations are permissiblerelative to which resources) that the requesting client (and its user)are permitted when utilizing the service specified in the authorizationtoken request. Through Internet 514, the resource server that invokedthe policy engine can return, to cloud-wide OAuth authorization server502, an indication of the permitted scope of access for the client (oruser thereof) identified in the authorization token request. Forexample, policy engine 518A may determine, based on some of policies520AA, that client 512AA has a first scope of access relative toservices provided by resource server 516A, while client 512AB has asecond scope of access relative to services provided by resource server516A. Policy engine 518A may determine, based on some of policies 520AB,that client 512BA has a third scope of access relative to servicesprovided by resource server 516A, while client 512BB has a fourth scopeof access relative to services provided by resource server 516A.Continuing the example, policy engine 518B may determine, based on someof policies 520BA, that client 512AA has a fifth scope of accessrelative to services provided by resource server 516B, while client512AB has a sixth scope of access relative to services provided byresource server 516B. Policy engine 518B may determine, based on some ofpolicies 520BB, that client 512BA has a seventh scope of access relativeto services provided by resource server 516B, while client 512BB has aneighth scope of access relative to services provided by resource server516B. The first through eighth scopes of access referenced in theforegoing example all may differ from each other.

Cloud-wide OAuth authorization server 502 can receive, over Internet514, from resource servers 516A and 516B, indications of scopes ofaccess that pertain to various authorization token requests that server502 forwarded to those resource servers. In response to receiving suchindications of scopes of access, Cloud-wide OAuth authorization server502 can generate authorization tokens that specify that certain clientsor users have the corresponding scopes of access relative to servicesprovided by the resource servers from which those scopes of access werereceived. Cloud-wide OAuth authorization server 502 can return, overInternet 514, such authorization tokens back to the various clients512AA, 512AB, 512BA, and 512BB from which server 502 previously receivedthe corresponding authorization token requests. Clients 512AA, 512AB,512BA, and 512BB receive these tokens over Internet 514 and thereaftercan present these authorization tokens to resource servers 516A and 516Bwhen requesting services from those resource servers. Resource servers516A and 516B can inspect the scopes of access contained within thoseauthorization tokens in order to determine whether the requesting clientis permitted to utilize a service to perform a specified operationrelative to a specified resource.

In an embodiment described above, resource servers 516A and 516B executepolicy engines 516A and 516B, respectively, and return indications ofscopes of access to cloud-wide OAuth authorization server 502, whichgenerates authorization token based on those scopes. However, in analternative embodiment of the invention, instead of returningindications of scopes of access to cloud-wide OAuth authorization server502, resource servers 516A and 516B can register, with server 502, theactual policies (e.g., policies 520AA and 520AB for resource server516A, and policies 520BA and 520BB for resource server 516B) that areapplicable to each identity domain. In such an alternative embodiment ofthe invention, cloud-wide OAuth authorization server 502 itself canevaluate the policies in the applicable subset against the client's (oruser's) attributes obtained from a cloud-wide identity store. Thus, insuch an alternative embodiment, cloud-wide OAuth authorization server502 itself can determine, based on the result of the evaluation, thescope of access that is to be specified in the authorization token to bereturned to the request-originating client. In such an alternativeembodiment, cloud-wide OAuth authorization server 502 might not need toforward authorization token requests to the resource servers.

Bundled Authorization Requests

Typically, a client application requesting services on behalf of aparticular user will end up requesting access to multiple differentservices for that user. For example, the client application might end uprequesting access to a storage service, a document service, and amessaging service. These services might be offered by different resourceservers. Without enhancement, the client application might end up makingthree separate token requests to the OAuth authorization server. Thiscan be the case even if the client application has some foreknowledgethat eventually all three services will be requested on behalf of theparticular user.

In one embodiment of the invention, to avoid such an inefficientprocess, a client application can bundle multiple access requests forseparate services—offered by separate resource servers—into a singletoken request that the client application issues to the OAuthauthorization server. In response to such a bundled request, the OAuthauthorization server can obtain authorization decisions from each of theresource servers that provide the services requested. The OAuthauthorization server can then generate a single token that includesaccess scope information resulting from each such resource server'sauthorization decision. The OAuth authorization server can return thissingle token to the client application. The client application can thensupply this token to any of the resource servers that provide any of theservices requested in the bundled request.

FIG. 7 is a flow diagram that illustrates an example of a technique forgenerating a single token usable to request services from multipleresource servers, according to an embodiment of the invention. In block702, an OAuth authorization server receives, from a client application,a token request that identifies multiple services. In block 703, inresponse to receiving the token request, the OAuth authorization servercreates a new multi-service token. In block 704, the OAuth authorizationserver sets the current service to be the first service specified in thetoken request. In block 706, the OAuth authorization server selects,from a group of resource servers, a particular resource server thatprovides the current service. In block 708, the OAuth authorizationserver determines, based on scope information obtained from theparticular resource server, a scope of access that the clientapplication is permitted to have relative to the current service. Inblock 710, the OAuth authorization server adds, to the multi-servicetoken, data indicating the scope of access for the current service. Inblock 712, the OAuth authorization server determines whether the tokenrequest identifies any further services for which access scope data hasnot yet been added to the multi-service token. If so, then controlpasses to block 714. Otherwise, control passes to block 716.

In block 714, the OAuth authorization server sets the current service tobe the next service specified in the token request. Control passes backto block 706.

Alternatively, in block 716, the OAuth authorization server returns themulti-service token to the client application. The technique describedwith reference to FIG. 7 then concludes.

Pluggable Authorization Policies

In one embodiment, the OAuth authorization server does not need to makedecisions as to access scope for services that are provided by resourceservers. In such an embodiment, the resource servers make thesedecisions instead based on their own maintained authorization policies,and the OAuth authorization server generates a token that specifiesaccess scope determined based on these decisions. The OAuthauthorization server can make callbacks to resource servers in order todetermine access scope. As a result, tenants can “plug in” desiredauthorization policies to the OAuth authorization system by configuringthose authorization policies within the resource servers deployed totheir identity domains.

FIGS. 8A-B show a flow diagram that illustrates an example of atechnique for plugging in resource server-maintained authorizationpolicies to an OAuth authorization server, according to an embodiment ofthe invention. Referring first to FIG. 8A, in block 802, a resourceserver receives an authorization policy from a service administratorfrom a particular identity domain. The resource server may havedifferent service administrators for different identity domains. Inblock 804, in response to receiving the authorization policy, theresource server determines the identity domain in which the serviceadministrator resides. In block 806, the resource server stores amapping between the authorization policy and the identity domain. Inblock 808, an OAuth authorization server receives, from theauthorization administrator of the identity domain, a plug-in commandthat specifies a URL for the resource server. In block 810, in responseto receiving the plug-in command, the OAuth authorization serverdetermines an identity domain in which the authorization administratorresides. In block 812, the OAuth authorization server stores a mappingbetween the identity domain and the URL for the resource server.

Referring next to FIG. 8B, in block 814, the OAuth authorization serverreceives a token request from a client application in a particularidentity domain. In block 816, in response to receiving the tokenrequest, the OAuth authorization server selects, from potentiallymultiple different URLs, a particular URL that is mapped to theparticular identity domain in which the client application resides. Inblock 818, the OAuth authorization server requests scope informationfrom the resource server located at the particular URL. The request mayindicate the particular identity domain and the client application. Inblock 820, the resource server located at the particular URL selects,from potentially multiple different authorization policies, a particularauthorization policy that is mapped to the particular identity domain.In block 822, the resource server generates scope of access informationbased on the identity of the client application and the particularauthorization policy. The scope of access information indicates thescope of access (e.g., permitted and forbidden operations) that theclient application has relative to the services provided by the resourceserver. In block 824, the resource server returns the scope of accessinformation to the OAuth authorization server. In block 826, the OAuthauthorization server generates a token that specifies the scope ofaccess information. In block 828, the OAuth authorization server returnsthe token to the client application.

Extended OAuth Request Format and Custom Token Attributes

In an embodiment, a token request can include data items that are not apart of the standard OAuth specification; the token request format canbe extended beyond the standard to enhance the OAuth authorizationsystem capabilities. For example, the token request can includeattribute values pertaining to the human user on whose behalf the clientapplication is requesting a token from the OAuth authorization server. Aresource server might benefit from obtaining such user attribute valuesin order to decide access scope on the basis of those attribute values.Thus, extending the information that can be included in the tokenrequest can enable resource servers to make more sophisticated accessscope decisions. The authorization policies that are maintained by theresource servers can specify more sophisticated criteria that involveattributes that otherwise would not be considered because they otherwisewould not be available to the resource server. Instead of being limitedto criteria related to client application attributes, authorizationpolicies can specify criteria related to human user attributes. Thesehuman user attributes can be maintained in an LDAP-based identity storethat is partitioned by identity domain.

In one embodiment, an OAuth authorization server can insert userattributes into a token. The OAuth authorization server can fetch suchuser attributes from a user profile that can be stored in an LDAPdirectory. The OAuth authorization server can send the token, includingthe user attributes, to a client application so that the clientapplication can present that token to a resource server. The resourceserver can make policy decisions based at least in part on the userattributes included in the token. For example, a resource server mightneed to know a user's subscription identifier in order to make anauthorization decision. The subscription identifier might be stored inthe user's profile. At the time of generating the token, the OAuthauthorization server can read the user's profile information from adirectory. The OAuth authorization server can read the subscriptionidentifier from the user's profile information.

In one embodiment, the OAuth authorization server determines, based onan OAuth administrator-defined configuration, which kinds of externalinformation, such as user attributes, need to be inserted into eachtoken that the OAuth authorization server generates. The OAuthauthorization server obtains and inserts the designated information intoeach token that the server generates. The OAuth authorization server canobtain information from any service and can insert that information intoa token; user attribute information is merely one kind of informationthat can be obtained and inserted. The OAuth authorization server canobtain such information from sources other than LDAP directories also.For example, the OAuth authorization server can obtain such informationfrom web services or other executing programs.

FIG. 6 is a flow diagram that illustrates an example of a technique foraugmenting a token with user-specific attributes, according to anembodiment of the invention. In block 602, an OAuth authorization serverreceives an administrator-defined configuration that specifies a set ofuser attributes. For example, the set of user attributes might include:department, security level, etc. It should be noted that these are thenames of the attributes rather than the specific values thereof. Inblock 604, the OAuth authorization server stores theadministrator-defined configuration. In block 606, the OAuthauthorization server receives a token request from a client application.In block 608, the OAuth authorization server determines an identity of auser based on the token request. In block 610, the OAuth authorizationserver determines a scope of access based on the token request. Forexample, the OAuth authorization server can use techniques describedabove to determine the scope of access based on resource server-providedauthorization policies. In block 612, the OAuth authorization retrieves,from a repository, values of the configuration-specified attributes forthe identified user. In block 614, the OAuth authorization serverinserts, into a new token, both (a) the values of theconfiguration-specified attributes for the identified user and (b) thescope of access. In block 616, the OAuth authorization server returnsthe new token to the client application in response to the tokenrequest. Thereafter, authorization decisions can be made based at leastin part on the values of the user attributes specified in the token thatthe client application supplies with each request to access a resourceprovided by a resource server.

Client Plug-Ins Permitting Diverse Client Profile Repositories

Each tenant in the cloud computing environment can have multiple clientapplications deployed to its separate identity domain. Each such clientapplication can have a client profile. Some tenants might want to storeclient profiles in an LDAP directory. Other tenants might want to storeclient profiles in a configuration file. Yet other tenants might want tostore client profiles in a database. In one embodiment of the invention,the OAuth authorization server provides a pluggable implementation forclients. The repositories into which a tenant's client profiles arestored can be configured on a per-tenant basis.

When a client application makes a request, the client supplies, to theOAuth authorization server, an identifier and a password that can beused to authenticate that client application prior to the performance ofauthorization procedures. The OAuth authorization server can relay theclient application's identifier and password to the appropriate plug-inso that the client application can be authenticated. The plug-in canaccess the repository in which the client application's profile isstored, regardless of the form that the repository takes. In oneembodiment, for each identity domain, the OAuth authorization serverstores configuration information that indicates the location of theplug-in that can access the client profiles for that identity domain.The OAuth authorization server can relay authorization requests to theappropriate plug-in based on this configuration information.

FIG. 9 is a flow diagram that illustrates an example of a technique forrouting an authentication request to a client-specific plug-in modulethat accesses a client-specific user identity repository, according toan embodiment of the invention. In block 902, an OAuth authorizationserver receives, from a first administrator, a first URL of a firstplug-in for a first type of user identity repository. For example, thefirst type of user identity repository might be a relational database.The OAuth authorization server may also receive, from the firstadministrator, information specifying a first type of client applicationthat the first plug-in is supposed to service. In block 904, the OAuthauthorization server stores a first mapping between the first type ofclient application and the first URL. Thus, the first plug-in becomesregistered with the OAuth authorization server. In block 906, the OAuthauthorization server receives, from a second administrator, a second URLof a second plug-in for a second type of user identity repository. Forexample, the second type of user identity repository might be an LDAPdirectory. The OAuth authorization server may also receive, from thesecond administrator, information specifying a second type of clientapplication that the second plug-in is supposed to service. In block908, the OAuth authorization server stores a second mapping between thesecond type of client application and the second URL. Thus, the secondplug-in becomes registered with the OAuth authorization server.

In block 910, the OAuth authorization server receives a userauthentication request from a particular client application having aparticular client application type. The user authentication request mayspecify a user name and a password. In block 912, the OAuthauthorization server locates a particular mapping (e.g., the firstmapping or the second mapping) that specifies the particular clientapplication type. In block 914, the OAuth authorization serverdetermines a particular URL (e.g., the first URL or the second URL) thatis specified in the particular mapping. In block 916, the OAuthauthorization server forwards the user authentication request to aparticular plug-in (e.g., the first plug-in or the second plug-in) thatis located at the particular URL. In block 918, the particular plug-inaccesses the particular type of user identity repository (e.g., thefirst type of user identity repository or the second type of useridentity repository) that the particular plug-in is designed to access.In block 920, the particular plug-in uses the user name and passwordspecified in the forwarded user authentication request to authenticatethe user of the particular client application based on informationcontained in the particular type of user identity repository. In oneembodiment, the particular plug-in can inform the OAuth authorizationserver as to the results of the authentication attempt (success orfailure).

Service Profile-Specific Token Attributes

According to an embodiment, attribute values can be defined at an OAuthservice profile level. For example, a token time-out value can bedefined within an OAuth service profile. An OAuth service profile mayindicate that all tokens that are issued to client applications to whichthat profile applies expire 8 hours after issuance. Thus, when the OAuthauthorization server generates tokens for client applications to whichthat OAuth service profile applies, the OAuth authorization server cangenerate tokens that expire 8 hours after issuance. Different OAuthservice profiles might indicate different values for that sameattribute, though, so that tokens that the OAuth authorization servergenerates for client application in different identity domains mighthave different time-out values. Such attribute values can be OAuthservice profile-specific.

FIG. 10 is a flow diagram that illustrates an example of a technique forgenerating tokens that have identity domain-specific token attributes,according to an embodiment of the invention. In block 1002, an OAuthauthorization server receives, from an administrator of a first identitydomain, a first service profile that specifies a first value for aparticular token attribute. For example, the token attribute can be“time-out” and the first value can be “8 hours.” In block 1004, inresponse to receiving the first service profile, the OAuth authorizationserver stores a first mapping between the first service profile and thefirst identity domain. In block 1006, the OAuth authorization serverreceives, from an administrator of a second identity domain, a secondservice profile that specifies a second value for the particular tokenattribute. For example, the token attribute can again be “time-out” andthe second value can be “1 hour.” In block 1008, in response toreceiving the second service profile, the OAuth authorization serverstores a second mapping between the second service profile and thesecond identity domain.

In block 1010, the OAuth authorization server receives a token requestfrom a client application that is contained in a particular identitydomain. In block 1012, the OAuth authorization server determines, basedon the stored mappings, a particular service profile that is mapped tothe particular identity domain. In block 1014, the OAuth authorizationserver reads the value of the particular token attribute from theparticular service profile. In block 1016, the OAuth authorizationserver generates a new token that contains the particular tokenattribute and the corresponding value from the particular serviceprofile. For example, the new token can indicate the “time-out”attribute and the corresponding value that is specified in the profilethat is mapped to the particular client application's identity domain.In block 1018, the OAuth authorization server returns the new token tothe particular client application in response to the token request.

Resource Server Token Attribute Overriding

Although a particular OAuth service profile can specify various valuesfor various attributes, such that the OAuth authorization server willgenerate tokens possessing characteristics conformant to those valuesfor client applications to which the particular OAuth service profileapplies, in one embodiment, individual resource servers can overridethese values for specified attributes. For example, a particularresource server might specify that a time-out attribute value for theservices that it provides is to be only 10 minutes, rather than 8 hours.In an embodiment, if a resource server specifies a value for aparticular attribute, that value takes precedence over a value specifiedfor the same particular attribute in an OAuth service profile.

Thus, in one embodiment of the invention, resource servers inheritattribute values from OAuth service profiles, but those resource serverscan optionally override those inherited attribute values by specifyingdifferent resource server-specific attribute values. In such anembodiment, if a resource server does not override the attribute valuespecified by the applicable OAuth service profile, then the attributevalue specified by the OAuth service profile remains valid, and theresource server will communicate that attribute value to the OAuthauthorization server as part of the access scope information that theOAuth authorization server uses to generate the token that is returnedto the client application.

In one embodiment of the invention, default attribute values also can bedefined separately at the identity domain level, such that multipleseparate OAuth service profiles within the same identity domain caninherit those attribute values. In such an embodiment, each OAuthservice profile can override the attribute values it inherits from theidentity domain in the same manner that each resource server canoverride the attribute values that it inherits from the OAuth serviceprofile.

FIG. 11 is a flow diagram that illustrates an example of a technique forgenerating tokens containing token attributes having values that areoverridden by resource servers, according to an embodiment of theinvention. In block 1102, an OAuth authorization server receives, froman administrator of an identity domain, a service profile that specifiesa first value for a particular token attribute. For example, the tokenattribute can be “time-out” and the first value can be “8 hours.” Inblock 1104, in response to receiving the service profile, the OAuthauthorization server stores a mapping between the service profile andthe identity domain. In block 1106, a resource server receives, from anadministrator of a resource server, a resource server-specific profilethat specifies a second value for the particular token attribute. Forexample, the token attribute can again be “time-out” and the secondvalue can be “10 minutes.” In block 1108, in response to receiving theresource-server specific profile, the resource server stores theresource server-specific profile.

In block 1110, the OAuth authorization server receives a token requestfrom a client application that is contained in the identity domain. Inblock 1112, the OAuth authorization server determines a particularservice profile that is mapped to the identity domain. In block 1114,the OAuth authorization server reads the service profile-specific valuefor the particular token attribute from the particular service profile.In block 1116, the OAuth authorization server determines that aparticular resource server provides the particular service specified inthe token request. In block 1118, in response to determining that theparticular resource server provides the particular service, the OAuthauthorization server asks the particular resource server for resourceserver-specific values. In block 1120, the OAuth authorizationdetermines whether a particular resource-specific value for theparticular attribute was received from the particular resource server.If so, then control passes to block 1122. Otherwise, control passes toblock 1124.

In block 1122, the OAuth authorization server generates a new token thatcontains the particular attribute and the resource server-specific valuerather than the service profile-specific value for the particularattribute. In this case, the resource server overrides the serviceprofile's value for the particular attribute. The OAuth authorizationserver returns the new token to the particular client application inresponse to the token request.

Alternatively, in block 1124, the OAuth authorization server generates anew token that contains the particular attribute and the serviceprofile-specific value for the particular attribute. In this case, theresource server inherits the service profile's value for the particularattribute. The OAuth authorization server returns the new token to theparticular client application in response to the token request.

Configurable Adaptive Access Call-Outs

Sometimes, a tenant might want users defined within its identity domainto be authenticated based on information that is more dynamic that justa static identity and password. For example, a tenant might want itsusers to be authenticated based on current geographical locations fromwhich those users are seeking access, or the Internet Protocol (IP)address from which those users are seeking access, or the time of day atwhich those users are seeking access. The use of such dynamicinformation in order to perform authentication is the basis of adaptiveaccess.

An adaptive access manager can build an access profile for each userover time. For example, the adaptive access manager might determine thata particular user typically logs into the system in between 8 a.m. and 5p.m. every day. On one particular night, though, the adaptive accessmanager may determine that the particular user has atypically attemptedto log into the system at midnight. This irregular access behavior mightindicate an illegitimate access attempt. For another example, theadaptive access manager might determine that a particular user logged infrom Boston on one evening and then logged in from San Francisco on thenext evening. The great distance between the two locations mightindicate an illegitimate access attempt. In response to detectingirregular access behavior, the adaptive access manager might cause anadditional challenge to be issued to the user as a part ofauthentication. For example, in addition to an identity and password,the adaptive access manager might cause a security question to be asked,the answer to which is known only to the true user. For another example,the adaptive access manager might send a single-use code to the user'sregistered e-mail address and cause the single-use code to be requestedin addition to the user's identity and password during authentication.In response to certain access patterns that cannot possibly belegitimate, the adaptive access manager might alternatively block theaccess attempt entirely, potentially locking the user's account untilremedial action can be taken.

In one embodiment of the invention, the OAuth authorization server makescalls to an external adaptive access manager in response to at leastcertain authentication requests from users. For example, the OAuthauthorization server might, based on specified policies, make calls tothe adaptive access manager whenever a new user is being registered froma mobile device. The adaptive access manager can respond to the OAuthauthorization server with information indicating whether an additionalcredential (or “second factor”) ought to be requested as part of theauthentication process. There can be multiple different adaptive accessmanagers. In one embodiment of the invention, each tenant can configureits “slice” of the OAuth authorization server to call a designatedadaptive access manager of the tenant's choice. Such a configuration canbe specified in a service profile, for example. Thus, a first tenant cancause the OAuth authorization server to make calls to a first adaptiveaccess manager when authenticating its users, while a second tenant cancause the OAuth authorization server to make calls to a second adaptiveaccess manager when authenticating its users. The OAuth authorizationserver can integrate with adaptive access managers provided by variousdifferent vendors.

FIG. 12 is a flow diagram that illustrates an example of a techniquewhereby a shared OAuth authorization server makes calls to differentregistered adaptive access managers for different identity domains in acloud computing environments, according to an embodiment of theinvention. In block 1202, an OAuth authorization server receives, froman administrator of a first identity domain, a first service profilethat specifies a first uniform resource locator (URL) for a firstadaptive access manager. In block 1204, in response to receiving thefirst service profile, the OAuth authorization server stores a mappingbetween the first service profile and the first identity domain. Inblock 1206, the OAuth authorization server receives, from anadministrator of a second identity domain distinct from the firstidentity domain, a second service profile that specifies a seconduniform resource locator (URL) for a second adaptive access managerdistinct from the first adaptive access manager. In block 1208, inresponse to receiving the second service profile, the OAuthauthorization server stores a mapping between the second service profileand the second identity domain.

In block 1210, the OAuth authorization server receives an authenticationrequest from a user associated with a particular identity domain. Inblock 1214, the OAuth authorization server determines an identity domainto which the authentication request pertains. In one embodiment, theauthentication request specifies an identity domain. In anotherembodiment, the OAuth authorization server can consult stored data todetermine an identity domain with which the specified user isassociated. In block 1216, the OAuth authorization server appliespolicies to determine whether an adaptive access manager should becalled in response to the authentication request. In one embodiment, thepolicies applied can be identity domain-specific policies, such that theselection of policies applied to the authentication request depends onthe identity domain from which the authentication request originated. Apolicy might indicate, for example, that an adaptive access manager isto be called only if the authentication request originates from a mobiledevice. The authentication request itself can specify whether itoriginated from a mobile device. If the evaluation of the applicablepolicies indicates that an adaptive access manager should be called,then control passes to block 1220. Otherwise, control passes to block1218.

In block 1218, the OAuth authorization server performs a standardauthentication process relative to the specified user, without callingany adaptive access manager. Under such circumstances, the techniquedescribed with reference to FIG. 12 concludes.

Alternatively, in block 1220, the OAuth authorization server makes acall to an adaptive access manager that is located at the URL specifiedin the service profile that is mapped to the identity domain determinedin block 1214. The call can include information pertaining to theauthentication request, such as the identity of the user and the originof the request (e.g., IP address, etc.). Based on such information, thecalled adaptive access manager can make a decision regarding whethersome stronger form of authentication, beyond a simple password, shouldbe required. For example, the stronger form of authentication mightinvolve answering one or more challenge questions to which only theauthentic user would know the answer, and/or supplying a one-time codesent out-of-band to a text message address known to belong to theauthentic user. In block 1222, the OAuth authorization server receives,from the adaptive access manager called in block 1220, an indication atleast of whether stronger authentication should be performed. In oneembodiment, this indication may further indicate one or more kinds ofstronger authentication, some of which are discussed in examples above,that should be performed. In block 1224, the OAuth authorization serverdetermines, based on the adaptive access manager's response, whether toperform stronger authentication. If the adaptive access manager'sresponse indicates that stronger authentication should be performed,then control passes to block 1226. Otherwise, control passes back toblock 1218.

In block 1226, the OAuth authorization server attempts to authenticatethe user using a an authentication process that is stronger than, oradditional to, the standard authentication process. In one embodiment,this involves performing one or more types of stronger authenticationspecified by the adaptive access manager's response.

Using Representational State Transfer (Rest) for Consent Management

In a typical scenario, an application that is integrated with a website,such as a social media website or an e-mail website, might request, froma user, permission for the application to access personal informationthat the website maintains about the user, such as the user's contactlist. The user can grant or deny this permission. The process by whichan application asks for such permission is consent management. Thepermission, if granted, is consent. At the time that the applicationrequests consent from the user, the website typically will authenticatethe user.

Often, in the process of requesting consent, an application will use aHypertext Transfer Protocol (HTTP)-based redirect operation in order tocause the user's browser to load a page from the website that possessesthe user's information that the application seeks to access. Throughsuch a page, the website will authenticate the user by requesting theuser's identity and password. After authenticating the user, the websitecan disclose, to the user, the identity of the application, and thescope of the information (e.g., a contact list) that the application isseeking to access. The user can then tell the website whether the usergives consent for the application to access that information on thewebsite. If the user gives consent, then the website can store thatconsent in association with the user's account. Later, the user can askthe website to show all of the consents that the user has given tovarious applications. The user can instruct the website to revokeselected consents if the user wishes. While an application has consent,the application can access the information to which the user hasconsented to access without requesting consent from that user again.

Under some circumstances, the interface through which an applicationneeds to obtain a user's consent is not an Internet browser-basedinterface. Such an alternative type of interface might not be designedto use or understand HTTP, and, as such, might not comprehend or reactappropriately to the HTTP redirects that are typically used as a part ofconsent management. For example, an application that is interacting witha user through a television interface might want to obtain the user'sconsent, but the television interface might not be designed to handleHTML redirects.

Therefore, in one embodiment of the invention, a mechanism is providedwhereby consent can be managed regardless of whether the interface isInternet browser-based or not, and regardless of whether the interfaceis HTTP-compliant, or not. In one embodiment of the invention, an OAuthauthorization server supports a RESTful interface for consentmanagement. For example, in response to a user pressing a certain buttonon his television remote control, software executing on the user'stelevision can invoke the RESTful interface of the server. Through theRESTful interface, the software can make a call back to the server andcan save the consent provided through the pressing of the button. Thesame RESTful interface can also be used to revoke such consent later on.Using the RESTful interface, a client application can render a customuser interface that the client application can use to drive the consentmanagement process. In an embodiment, no HTML-based redirects areinvolved in the REST-based consent management process. REST is describedin greater detail in Fielding, Roy Thomas, Architectural Styles and theDesign of Network-based Software Architectures, Doctoral dissertation,University of California, Irvine, 2000, which is incorporated byreference herein. REST is further discussed in U.S. Patent ApplicationPublication No. 2013/0081128 and in U.S. Patent Application PublicationNo. 2013/0086669, each of which is also incorporated by referenceherein.

FIG. 13 is a flow diagram that illustrates an example of a techniquewhereby an OAuth authorization server provides a Representational StateTransfer (REST) interface for consent management, according to anembodiment of the invention. In block 1302, an OAuth authorizationserver exposes a REST-based interface to a software application. Inblock 1304, the OAuth authorization server receives, from the softwareapplication, a REST-based request through the REST-based interface. TheREST-based request can specify a scope of information that is associatedwith a specified user. In block 1306, in response to the REST-basedrequest, the OAuth authorization server requests, from the softwareapplication, through the REST-based interface, an authenticationcredential (e.g., a password) associated with the specified user. Inblock 1308, the OAuth authorization server receives a credential fromthe software application through the REST-based interface. In block1310, the OAuth authorization server authenticates the specified userbased on the received credential. In block 1312, the OAuth authorizationserver asks the user, through the REST-based interface, whether the userconsents to having the software application access information specifiedby the scope of information. In block 1314, the OAuth authorizationserver receives the user's consent through the REST-based interface. Inblock 1316, the OAuth authorization server stores a mapping between thesoftware application and the scope of information. Thereafter, thesoftware application can access information falling within the scope ofinformation due to the stored mapping; the software application does notneed to re-obtain the user's consent to access the information. In someembodiments, the user can interact with the OAuth authorization serverthrough the REST-based interface to obtain a list of consents that theuser has previously granted to various entities, along with the scopesof information involved in each consent. In some embodiment, the usercan interface with the OAuth authorization server through the REST-basedinterface to revoke one or more previously granted consents. Suchrevocation can cause the OAuth authorization server to delete themapping that pertains to the revoked consent.

Single Sign-on for Mobile Applications

In the cloud computing environment, multiple applications from the samevendor may be executing in the context of the same identity domain. Whensuch an application is launched from a mobile device such as a smartphone, users may be bothered if they are required to provide a useridentity and password to log into that application after they havealready done so to log into another application from the same vendor.Mobile native applications have lacked a single sign-on mechanism. Thisdiffers from the Internet browser-based application paradigm, in whichcookies stored by the browser can keep track of whether a user haslogged into one website so that the user does not thereafter need to loginto another related website.

According to an embodiment of the invention, a mechanism is providedwhereby single sign-on functionality can be made available betweenmobile native applications. Using this mechanism, if a user logs intoone mobile native application by supplying a user identity and password,then the fact that the user logged into that mobile native applicationcan be used by other mobile native applications from the same vendor inorder to allow the user to access those other mobile native applicationswithout separately requiring the user to supply a user identity andpassword for each one. Essentially, the user can sign on to all of themobile native applications in a group of applications that belong to acircle of trust by signing into any of those mobile native applications.

In order to enable such single sign-on functionality for mobile nativeapplications, in one embodiment, a separate server-side store is createdfor each mobile device that can access the applications. Each of themobile native applications is first registered on the server, which isremote from all of the mobile devices. The first time that a particularmobile native application is launched on a mobile device, a registrationprocess is performed. Strong authentication, involving a second factor,may be performed as part of the registration process for each particularmobile native application. After each mobile native application in atrusted group has been registered with the server, authentication withany of those applications in the trusted group results in the creationof a user session that is shared between those applications, such thatno password challenge is issued to the user if the user launches any ofthe other applications in the trusted group while the session is active.A circle of trust including all of the application in the group ismaintained on the server.

In one embodiment, a separate device store is created on the server foreach mobile device. The user session initiated from a particular mobiledevice is stored within the device store for that mobile device. Theserver issues a client registration token to each application within thetrusted group that registers with the server. The client registrationtoken include three items of information: the hardware identifier of themobile device (e.g., Media Access Control (MAC) address) from which theapplication was launched, the identity of the user on whose behalf thetoken has been issued, and the identity of the application to which thetoken has been issued. Each of the applications in the trusted groupreceives the client registration token, which contains the same hardwareidentifier. The application identity differs between the tokenspossessed by the applications within the trusted group. The hardwareidentifier within the client registration token has been signed (e.g.,using encryption techniques) by the server.

Prior to the creation of the user session, when the first mobile nativeapplication in the trusted group launches, that application provides theclient registration token to the OAuth authorization server. The OAuthauthorization server authenticates the first mobile native applicationusing a password challenge and then stores a user session in theserver-side device store associated with the mobile device specified bythe client registration token. The user session can have a specifiedexpiration time. When another mobile native application in the sametrusted group launches, that application also provides the clientregistration token to the OAuth authorization server. Using the hardwareidentifier in the client registration token, the device store associatedwith the mobile device can be unlocked. The server can determine that itwas the signer of the hardware identifier in the token. The server candetermine that the device store associated with the mobile device havingthe hardware identifier already contains a valid user session. Inresponse to making this determination, the OAuth authorization servernotifies the mobile native application that no password challenge needsto be issued to the user; the user can use all of the mobile nativeapplications in the trusted group without any additional sign-onprocess, due to the existence of the valid user session in the devicestore.

In one embodiment of the invention, a single identity domain can containmultiple separate service profiles. For example, a first service profilecan be established for a first group of applications, and a secondservice profile can be established for a second group of applications.In an embodiment, all applications that are associated with a particularservice profile are placed within the same trusted group. Single sign-onfunctionality is available for applications within the same trustedgroup. A tenant who administers an identity domain can specify, for eachservice profile in its identity domain, the applications that areassociated with that service profile. Separate service profiles can becreated per department or employee role, for example.

FIG. 14 is a flow diagram that illustrates an example of a techniquewhereby a server maintains an active user session for multipleinterrelated applications that execute on a mobile device separate fromthe server, according to an embodiment of the invention. In block 1402,a server (potentially an OAuth authorization server) receives aregistration request from a first application executing on a firstmobile device. In block 1404, the server performs an authenticationprocess relative to the first application and its user. In block 1406,the server sends, to the first application, a first client registrationtoken that specifies (a) a hardware identifier of the first mobiledevice, (b) a user identity of the user that was authenticated, and (c)an identity of the first application. The first application stores thefirst client registration token.

In block 1408, the server receives a registration request from a secondapplication executing on the first mobile device. The second applicationis separate from the first application, but may belong to acircle-of-trust group to which the first application also belongs. Eachapplication is that circle-of-trust group may be a product of the samevendor, for example. In block 1410, the server performs anauthentication process relative to the second application and its user.In block 1412, the server sends, to the second application, a secondclient registration token that specifies (a) the same hardwareidentifier of the first mobile device, (b) the same user identity of theuser that was authenticated, and (c) an identity of the secondapplication, which differs from the identity of the first application.The second application stores the second client registration token. Theserver can also receive registration requests from applicationsexecuting on other mobile devices, such as a second mobile device. Theclient registration tokens that the server sends to such applicationswould each specify the hardware identifiers of the respective mobiledevices on which those applications executed.

In block 1414, the server receives a particular client registrationtoken from a particular application executing on a particular mobiledevice. For example, the particular mobile device might be the firstmobile device, a second mobile device separate from the first mobiledevice, or some other mobile device. Furthermore, the particularapplication might be the first application executing on the first mobiledevice, the second application executing on the first mobile device,some other application executing on the first mobile device, or someother application executing on some mobile device other than the firstmobile device. In block 1416, the server determines whether a usersession for the particular mobile device exists at the server. If a usersession for the particular mobile device exists, then control passes toblock 1424. Otherwise, control passes to block 1418.

In block 1418, the server instructs the particular application torequest an authentication credential from a user of the particularapplication. For example, the server can instruct the particularapplication to challenge the user of the particular application tosupply a password known to the server to be associated with the user. Inblock 1420, after verifying that the user-supplied authenticationcredential is legitimate, the server creates and stores a new usersession that is mapped to a unique identity of the particular mobiledevice. In an embodiment, this unique identity is the hardwareidentifier that is specified in the particular client registration tokenthat the server received in block 1414.

In block 1422, the server informs the particular application that theuser of the particular application has successfully signed on to theparticular application. Thereafter, the user of the particularapplication can access the functionality provided by the particularapplication for as long as the user remains signed on. In an embodiment,the user remains signed on for as long as the user session stored at theserver remains valid.

Alternatively, in block 1424, the server verifies that the hardwareidentifier specified in the particular client registration token matchesthe hardware identifier specified in the user session. As is discussedabove, the hardware identifier sent in each client registration tokenand the hardware identifier specified in the user session all can besigned by the server using encryption techniques, so that the hardwareidentifier cannot be forged. After the server verifies that the hardwareidentifiers match, control passes to block 1422. Under suchcircumstances, the server does not instruct the particular applicationto request an authentication credential as in block 1418; the user ofthe particular mobile device has already signed on previously, asevidenced by the existence of the server-side user session for thatparticular mobile device. Thus, in this manner, the server can providesingle sign-on functionality for applications executing on mobiledevices.

Mobile OAuth Service

The single sign-on technique for mobile applications discussed aboveworks securely enough assuming that the OAuth authorization server onlyprovides client registration tokens to legitimate mobile applications onthe mobile device at the time that those application register for thefirst time with the server. As part of enforcing security, strongauthentication—potentially involving a second factor—may be performedfor each mobile application at registration time to ensure that onlylegitimate applications receive client registration tokens. However,some hacking techniques still possibly may undermine even thesesafeguards. An application on a mobile device hypothetically couldmasquerade as some other application.

Therefore, in one embodiment of the invention, in order to confirm thatan application on a mobile device actually is the application that isclaims to be, an out-of-band verification mechanism is provided. OnApple iOS, a mechanism called APNS—Apple Push Notification Service—isprovided. APNS can be used to uniquely identify an application on amobile device. External sources that wish to communicate with mobileapplications can send push notifications through APNS to those mobileapplications on mobile devices. The APNS server guarantees that suchnotifications will be sent to the specific applications on the specificdevices for which those notifications are destined. This guarantee isbased on certificates that Apple has issued to each mobile device. Atthe time that an application registers for the APNS, that applicationpresents the mobile device's certificate to Apple's APNS server. TheAPNS server returns a device token to the application. The APNS serverstores an association between the device token and the application andthe mobile device on which the application executes. The application canpresent the device token to external sources that desire to sendnotifications to the application. These external sources can present thedevice token to the APNS server along with each notification that theexternal sources seek to send to the application. The APNS server thencan push each such notification to the application that is associatedwith that device token.

Thus, on at least some mobile devices, APNS can be used as a mechanismto send a message to an application on a device in a secure manner. APNScan be used as the out-of-band mechanism for registering an applicationwith the OAuth authorization server. The OAuth authorization server cansend the client registration token to the mobile application over APNSat the time that the mobile application initially registers with theOAuth authorization server, thereby ensuring that only the proper mobileapplication will receive that client registration token. A masqueradingclient will not be known to the APNS, and therefore will not receive aclient registration token pushed through APNS from the OAuthauthorization server. In one embodiment, during the mobile applicationregistration process, the mobile application provides the device tokenreceived from APNS to the OAuth authorization server, and thereafter theOAuth authorization server uses that device token to push information tothat mobile application whenever the OAuth authorization servercommunicates information to that mobile application.

In an alternative embodiment of the invention, the OAuth authorizationserver does not send the entire client registration token to the mobileapplication over APNS. Instead, the OAuth authorization server splitsthe client registration token into two encrypted parts. The OAuthauthorization server sends half of the client registration token overAPNS to the mobile application. The OAuth authorization server sends theother half of the client registration token to the mobile applicationusing a Hypertext Transfer Protocol (HTTP) channel—typically the samechannel that the mobile application used to register with the OAuthauthorization server. After receiving both halves and combining them,the mobile application has a complete client registration token. Thistechnique can be even more secure than sending the entire clientregistration through APNS.

Some mobile devices do not execute Apple iOS and are unable to use APNS.In one embodiment of the invention, at least some mobile devices, suchas devices that execute the Android operating system, receive clientregistration tokens using a similar technique as that described aboveexcept with Google Cloud Messaging (GCM) being used as the out-of-bandtoken transmission channel instead of APNS.

FIG. 15 is a flow diagram that illustrates an example of a technique forsecurely sending a client registration token to a mobile device throughout-of-band channels so that the mobile device can subsequently use thatclient registration token to achieve single sign-on functionality,according to an embodiment of the invention. In block 1502, an OAuthauthorization server receives, in a registration request from anapplication that executes on a mobile device, a device token thatuniquely identifies the application and that the application previouslyreceived from a service as part of a prior registration process in whichthe application engaged with the service. The service is separate from,and not provided or controlled by, the OAuth authorization server or theshared cloud computing environment in which the OAuth authorizationserver executes. In one embodiment, the service is Apple PushNotification Service (APNS). In another embodiment, the service isGoogle Cloud Messaging (GCM). In other embodiments, the service can besome other notification or messaging service that provides, toapplications, device tokens that uniquely identify those applications.Such services often are connected with application stores from whichmobile devices can download applications. Such application storestypically assign such unique application identifiers to suchapplications as a part of the process of making such applicationsavailable within those application stores.

In block 1504, the OAuth authorization server generates a clientregistration token in response to the application's registrationrequest. As is discussed above in connection with FIG. 14, such a clientregistration token in one embodiment specifies, among other information,a MAC address of the mobile device on which the application executes. Inblock 1506, the OAuth authorization server splits the clientregistration token into two parts. Each such part contains informationthat the other part does not. In block 1508, the OAuth authorizationserver encrypts each part of the client registration token.

In block 1510, the OAuth authorization server sends, to the service fromwhich the mobile application previously received the device token, boththe device token and a notification that specifies a first encryptedpart of the client registration token. The service subsequently canverify the authenticity of the device token and push the notification,including the first encrypted part of the client registration token, tothe application on the mobile device. Both the application and themobile device are uniquely identified by the device token. The devicetoken can specify the MAC address of the mobile device, which theservice can use to address the push notification in a network.

In block 1512, the OAuth authorization server sends a second encryptedpart of the client registration token to the mobile device through aHypertext Transfer Protocol (HTTP) channel that is not related to theservice used to send the first encrypted part. In one embodiment, thisHTTP channel is the same channel through which the mobile device sentthe registration request that the OAuth authorization server received inblock 1502. The mobile device subsequently can receive both encryptedparts of the client registration token, decrypt each part, and combinethe decrypted parts into the complete client registration token.Thereafter, the mobile device can store the client registration tokenand use the client registration token as described above in connectionwith FIG. 14 to achieve single sign-on functionality for interrelatedapplications that execute on that mobile device.

Hardware Overview

FIG. 16 depicts a simplified diagram of a distributed system 1600 forimplementing one of the embodiments. In the illustrated embodiment,distributed system 1600 includes one or more client computing devices1602, 1604, 1606, and 1608, which are configured to execute and operatea client application such as a web browser, proprietary client (e.g.,Oracle Forms), or the like over one or more network(s) 1610. Server 1612may be communicatively coupled with remote client computing devices1602, 1604, 1606, and 1608 via network 1610.

In various embodiments, server 1612 may be adapted to run one or moreservices or software applications provided by one or more of thecomponents of the system. In some embodiments, these services may beoffered as web-based or cloud services or under a Software as a Service(SaaS) model to the users of client computing devices 1602, 1604, 1606,and/or 1608. Users operating client computing devices 1602, 1604, 1606,and/or 1608 may in turn utilize one or more client applications tointeract with server 1612 to utilize the services provided by thesecomponents.

In the configuration depicted in the figure, the software components1618, 1620 and 1622 of system 1600 are shown as being implemented onserver 1612. In other embodiments, one or more of the components ofsystem 1600 and/or the services provided by these components may also beimplemented by one or more of the client computing devices 1602, 1604,1606, and/or 1608. Users operating the client computing devices may thenutilize one or more client applications to use the services provided bythese components. These components may be implemented in hardware,firmware, software, or combinations thereof. It should be appreciatedthat various different system configurations are possible, which may bedifferent from distributed system 1600. The embodiment shown in thefigure is thus one example of a distributed system for implementing anembodiment system and is not intended to be limiting.

Client computing devices 1602, 1604, 1606, and/or 1608 may be portablehandheld devices (e.g., an iPhone®, cellular telephone, an iPad®,computing tablet, a personal digital assistant (PDA)) or wearabledevices (e.g., a Google Glass® head mounted display), running softwaresuch as Microsoft Windows Mobile®, and/or a variety of mobile operatingsystems such as iOS, Windows Phone, Android, BlackBerry 17, Palm OS, andthe like, and being Internet, e-mail, short message service (SMS),Blackberry®, or other communication protocol enabled. The clientcomputing devices can be general purpose personal computers including,by way of example, personal computers and/or laptop computers runningvarious versions of Microsoft Windows®, Apple Macintosh®, and/or Linuxoperating systems. The client computing devices can be workstationcomputers running any of a variety of commercially-available UNIX® orUNIX-like operating systems, including without limitation the variety ofGNU/Linux operating systems, such as for example, Google Chrome OS.Alternatively, or in addition, client computing devices 1602, 1604,1606, and 1608 may be any other electronic device, such as a thin-clientcomputer, an Internet-enabled gaming system (e.g., a Microsoft Xboxgaming console with or without a Kinect® gesture input device), and/or apersonal messaging device, capable of communicating over network(s)1610.

Although exemplary distributed system 1600 is shown with four clientcomputing devices, any number of client computing devices may besupported. Other devices, such as devices with sensors, etc., mayinteract with server 1612.

Network(s) 1610 in distributed system 1600 may be any type of networkfamiliar to those skilled in the art that can support datacommunications using any of a variety of commercially-availableprotocols, including without limitation TCP/IP (transmission controlprotocol/Internet protocol), SNA (systems network architecture), IPX(Internet packet exchange), AppleTalk, and the like. Merely by way ofexample, network(s) 1610 can be a local area network (LAN), such as onebased on Ethernet, Token-Ring and/or the like. Network(s) 1610 can be awide-area network and the Internet. It can include a virtual network,including without limitation a virtual private network (VPN), anintranet, an extranet, a public switched telephone network (PSTN), aninfra-red network, a wireless network (e.g., a network operating underany of the Institute of Electrical and Electronics (IEEE) 1602.11 suiteof protocols, Bluetooth®, and/or any other wireless protocol); and/orany combination of these and/or other networks.

Server 1612 may be composed of one or more general purpose computers,specialized server computers (including, by way of example, PC (personalcomputer) servers, UNIX® servers, mid-range servers, mainframecomputers, rack-mounted servers, etc.), server farms, server clusters,or any other appropriate arrangement and/or combination. In variousembodiments, server 1612 may be adapted to run one or more services orsoftware applications described in the foregoing disclosure. Forexample, server 1612 may correspond to a server for performingprocessing described above according to an embodiment of the presentdisclosure.

Server 1612 may run an operating system including any of those discussedabove, as well as any commercially available server operating system.Server 1612 may also run any of a variety of additional serverapplications and/or mid-tier applications, including HTTP (hypertexttransport protocol) servers, FTP (file transfer protocol) servers, CGI(common gateway interface) servers, JAVA® servers, database servers, andthe like. Exemplary database servers include without limitation thosecommercially available from Oracle, Microsoft, Sybase, IBM(International Business Machines), and the like.

In some implementations, server 1612 may include one or moreapplications to analyze and consolidate data feeds and/or event updatesreceived from users of client computing devices 1602, 1604, 1606, and1608. As an example, data feeds and/or event updates may include, butare not limited to, Twitter® feeds, Facebook® updates or real-timeupdates received from one or more third party information sources andcontinuous data streams, which may include real-time events related tosensor data applications, financial tickers, network performancemeasuring tools (e.g., network monitoring and traffic managementapplications), clickstream analysis tools, automobile trafficmonitoring, and the like. Server 1612 may also include one or moreapplications to display the data feeds and/or real-time events via oneor more display devices of client computing devices 1602, 1604, 1606,and 1608.

Distributed system 1600 may also include one or more databases 1614 and1616. Databases 1614 and 1616 may reside in a variety of locations. Byway of example, one or more of databases 1614 and 1616 may reside on anon-transitory storage medium local to (and/or resident in) server 1612.Alternatively, databases 1614 and 1616 may be remote from server 1612and in communication with server 1612 via a network-based or dedicatedconnection. In one set of embodiments, databases 1614 and 1616 mayreside in a storage-area network (SAN). Similarly, any necessary filesfor performing the functions attributed to server 1612 may be storedlocally on server 1612 and/or remotely, as appropriate. In one set ofembodiments, databases 1614 and 1616 may include relational databases,such as databases provided by Oracle, which are adapted to store,update, and retrieve data in response to SQL-formatted commands.

FIG. 17 is a simplified block diagram of one or more components of asystem environment 1700 by which services provided by one or morecomponents of an embodiment system may be offered as cloud services, inaccordance with an embodiment of the present disclosure. In theillustrated embodiment, system environment 1700 includes one or moreclient computing devices 1704, 1706, and 1708 that may be used by usersto interact with a cloud infrastructure system 1702 that provides cloudservices. The client computing devices may be configured to operate aclient application such as a web browser, a proprietary clientapplication (e.g., Oracle Forms), or some other application, which maybe used by a user of the client computing device to interact with cloudinfrastructure system 1702 to use services provided by cloudinfrastructure system 1702.

It should be appreciated that cloud infrastructure system 1702 depictedin the figure may have other components than those depicted. Further,the embodiment shown in the figure is only one example of a cloudinfrastructure system that may incorporate an embodiment of theinvention. In some other embodiments, cloud infrastructure system 1702may have more or fewer components than shown in the figure, may combinetwo or more components, or may have a different configuration orarrangement of components.

Client computing devices 1704, 1706, and 1708 may be devices similar tothose described above for 1602, 1604, 1606, and 1608.

Although exemplary system environment 1700 is shown with three clientcomputing devices, any number of client computing devices may besupported. Other devices such as devices with sensors, etc. may interactwith cloud infrastructure system 1702.

Network(s) 1710 may facilitate communications and exchange of databetween clients 1704, 1706, and 1708 and cloud infrastructure system1702. Each network may be any type of network familiar to those skilledin the art that can support data communications using any of a varietyof commercially-available protocols, including those described above fornetwork(s) 1610.

Cloud infrastructure system 1702 may comprise one or more computersand/or servers that may include those described above for server 1612.

In certain embodiments, services provided by the cloud infrastructuresystem may include a host of services that are made available to usersof the cloud infrastructure system on demand, such as online datastorage and backup solutions, Web-based e-mail services, hosted officesuites and document collaboration services, database processing, managedtechnical support services, and the like. Services provided by the cloudinfrastructure system can dynamically scale to meet the needs of itsusers. A specific instantiation of a service provided by cloudinfrastructure system is referred to herein as a “service instance.” Ingeneral, any service made available to a user via a communicationnetwork, such as the Internet, from a cloud service provider's system isreferred to as a “cloud service.” Typically, in a public cloudenvironment, servers and systems that make up the cloud serviceprovider's system are different from the customer's own on-premisesservers and systems. For example, a cloud service provider's system mayhost an application, and a user may, via a communication network such asthe Internet, on demand, order and use the application.

In some examples, a service in a computer network cloud infrastructuremay include protected computer network access to storage, a hosteddatabase, a hosted web server, a software application, or other serviceprovided by a cloud vendor to a user, or as otherwise known in the art.For example, a service can include password-protected access to remotestorage on the cloud through the Internet. As another example, a servicecan include a web service-based hosted relational database and ascript-language middleware engine for private use by a networkeddeveloper. As another example, a service can include access to an emailsoftware application hosted on a cloud vendor's web site.

In certain embodiments, cloud infrastructure system 1702 may include asuite of applications, middleware, and database service offerings thatare delivered to a customer in a self-service, subscription-based,elastically scalable, reliable, highly available, and secure manner. Anexample of such a cloud infrastructure system is the Oracle Public Cloudprovided by the present assignee.

In various embodiments, cloud infrastructure system 1702 may be adaptedto automatically provision, manage and track a customer's subscriptionto services offered by cloud infrastructure system 1702. Cloudinfrastructure system 1702 may provide the cloud services via differentdeployment models. For example, services may be provided under a publiccloud model in which cloud infrastructure system 1702 is owned by anorganization selling cloud services (e.g., owned by Oracle) and theservices are made available to the general public or different industryenterprises. As another example, services may be provided under aprivate cloud model in which cloud infrastructure system 1702 isoperated solely for a single organization and may provide services forone or more entities within the organization. The cloud services mayalso be provided under a community cloud model in which cloudinfrastructure system 1702 and the services provided by cloudinfrastructure system 1702 are shared by several organizations in arelated community. The cloud services may also be provided under ahybrid cloud model, which is a combination of two or more differentmodels.

In some embodiments, the services provided by cloud infrastructuresystem 1702 may include one or more services provided under Software asa Service (SaaS) category, Platform as a Service (PaaS) category,Infrastructure as a Service (IaaS) category, or other categories ofservices including hybrid services. A customer, via a subscriptionorder, may order one or more services provided by cloud infrastructuresystem 1702. Cloud infrastructure system 1702 then performs processingto provide the services in the customer's subscription order.

In some embodiments, the services provided by cloud infrastructuresystem 1702 may include, without limitation, application services,platform services and infrastructure services. In some examples,application services may be provided by the cloud infrastructure systemvia a SaaS platform. The SaaS platform may be configured to providecloud services that fall under the SaaS category. For example, the SaaSplatform may provide capabilities to build and deliver a suite ofon-demand applications on an integrated development and deploymentplatform. The SaaS platform may manage and control the underlyingsoftware and infrastructure for providing the SaaS services. Byutilizing the services provided by the SaaS platform, customers canutilize applications executing on the cloud infrastructure system.Customers can acquire the application services without the need forcustomers to purchase separate licenses and support. Various differentSaaS services may be provided. Examples include, without limitation,services that provide solutions for sales performance management,enterprise integration, and business flexibility for largeorganizations.

In some embodiments, platform services may be provided by the cloudinfrastructure system via a PaaS platform. The PaaS platform may beconfigured to provide cloud services that fall under the PaaS category.Examples of platform services may include without limitation servicesthat enable organizations (such as Oracle) to consolidate existingapplications on a shared, common architecture, as well as the ability tobuild new applications that leverage the shared services provided by theplatform. The PaaS platform may manage and control the underlyingsoftware and infrastructure for providing the PaaS services. Customerscan acquire the PaaS services provided by the cloud infrastructuresystem without the need for customers to purchase separate licenses andsupport. Examples of platform services include, without limitation,Oracle Java Cloud Service (JCS), Oracle Database Cloud Service (DBCS),and others.

By utilizing the services provided by the PaaS platform, customers canemploy programming languages and tools supported by the cloudinfrastructure system and also control the deployed services. In someembodiments, platform services provided by the cloud infrastructuresystem may include database cloud services, middleware cloud services(e.g., Oracle Fusion Middleware services), and Java cloud services. Inone embodiment, database cloud services may support shared servicedeployment models that enable organizations to pool database resourcesand offer customers a Database as a Service in the form of a databasecloud. Middleware cloud services may provide a platform for customers todevelop and deploy various business applications, and Java cloudservices may provide a platform for customers to deploy Javaapplications, in the cloud infrastructure system.

Various different infrastructure services may be provided by an IaaSplatform in the cloud infrastructure system. The infrastructure servicesfacilitate the management and control of the underlying computingresources, such as storage, networks, and other fundamental computingresources for customers utilizing services provided by the SaaS platformand the PaaS platform.

In certain embodiments, cloud infrastructure system 1702 may alsoinclude infrastructure resources 1730 for providing the resources usedto provide various services to customers of the cloud infrastructuresystem. In one embodiment, infrastructure resources 1730 may includepre-integrated and optimized combinations of hardware, such as servers,storage, and networking resources to execute the services provided bythe PaaS platform and the SaaS platform.

In some embodiments, resources in cloud infrastructure system 1702 maybe shared by multiple users and dynamically re-allocated per demand.Additionally, resources may be allocated to users in different timezones. For example, cloud infrastructure system 1730 may enable a firstset of users in a first time zone to utilize resources of the cloudinfrastructure system for a specified number of hours and then enablethe re-allocation of the same resources to another set of users locatedin a different time zone, thereby maximizing the utilization ofresources.

In certain embodiments, a number of internal shared services 1732 may beprovided that are shared by different components or modules of cloudinfrastructure system 1702 and by the services provided by cloudinfrastructure system 1702. These internal shared services may include,without limitation, a security and identity service, an integrationservice, an enterprise repository service, an enterprise managerservice, a virus scanning and white list service, a high availability,backup and recovery service, service for enabling cloud support, anemail service, a notification service, a file transfer service, and thelike.

In certain embodiments, cloud infrastructure system 1702 may providecomprehensive management of cloud services (e.g., SaaS, PaaS, and IaaSservices) in the cloud infrastructure system. In one embodiment, cloudmanagement functionality may include capabilities for provisioning,managing and tracking a customer's subscription received by cloudinfrastructure system 1702, and the like.

In one embodiment, as depicted in the figure, cloud managementfunctionality may be provided by one or more modules, such as an ordermanagement module 1720, an order orchestration module 1722, an orderprovisioning module 1724, an order management and monitoring module1726, and an identity management module 1728. These modules may includeor be provided using one or more computers and/or servers, which may begeneral purpose computers, specialized server computers, server farms,server clusters, or any other appropriate arrangement and/orcombination.

In exemplary operation 1734, a customer using a client device, such asclient device 1704, 1706 or 1708, may interact with cloud infrastructuresystem 1702 by requesting one or more services provided by cloudinfrastructure system 1702 and placing an order for a subscription forone or more services offered by cloud infrastructure system 1702. Incertain embodiments, the customer may access a cloud User Interface(UI), cloud UI 1712, cloud UI 1714 and/or cloud UI 1716 and place asubscription order via these UIs. The order information received bycloud infrastructure system 1702 in response to the customer placing anorder may include information identifying the customer and one or moreservices offered by the cloud infrastructure system 1702 that thecustomer intends to subscribe to.

After an order has been placed by the customer, the order information isreceived via the cloud UIs, 1712, 1714 and/or 1716.

At operation 1736, the order is stored in order database 1718. Orderdatabase 1718 can be one of several databases operated by cloudinfrastructure system 1718 and operated in conjunction with other systemelements.

At operation 1738, the order information is forwarded to an ordermanagement module 1720. In some instances, order management module 1720may be configured to perform billing and accounting functions related tothe order, such as verifying the order, and upon verification, bookingthe order.

At operation 1740, information regarding the order is communicated to anorder orchestration module 1722. Order orchestration module 1722 mayutilize the order information to orchestrate the provisioning ofservices and resources for the order placed by the customer. In someinstances, order orchestration module 1722 may orchestrate theprovisioning of resources to support the subscribed services using theservices of order provisioning module 1724.

In certain embodiments, order orchestration module 1722 enables themanagement of business processes associated with each order and appliesbusiness logic to determine whether an order should proceed toprovisioning. At operation 1742, upon receiving an order for a newsubscription, order orchestration module 1722 sends a request to orderprovisioning module 1724 to allocate resources and configure thoseresources needed to fulfill the subscription order. Order provisioningmodule 1724 enables the allocation of resources for the services orderedby the customer. Order provisioning module 1724 provides a level ofabstraction between the cloud services provided by cloud infrastructuresystem 1700 and the physical implementation layer that is used toprovision the resources for providing the requested services. Orderorchestration module 1722 may thus be isolated from implementationdetails, such as whether or not services and resources are actuallyprovisioned on the fly or pre-provisioned and only allocated/assignedupon request.

At operation 1744, once the services and resources are provisioned, anotification of the provided service may be sent to customers on clientdevices 1704, 1706 and/or 1708 by order provisioning module 1724 ofcloud infrastructure system 1702.

At operation 1746, the customer's subscription order may be managed andtracked by an order management and monitoring module 1726. In someinstances, order management and monitoring module 1726 may be configuredto collect usage statistics for the services in the subscription order,such as the amount of storage used, the amount data transferred, thenumber of users, and the amount of system up time and system down time.

In certain embodiments, cloud infrastructure system 1700 may include anidentity management module 1728. Identity management module 1728 may beconfigured to provide identity services, such as access management andauthorization services in cloud infrastructure system 1700. In someembodiments, identity management module 1728 may control informationabout customers who wish to utilize the services provided by cloudinfrastructure system 1702. Such information can include informationthat authenticates the identities of such customers and information thatdescribes which actions those customers are authorized to performrelative to various system resources (e.g., files, directories,applications, communication ports, memory segments, etc.) Identitymanagement module 1728 may also include the management of descriptiveinformation about each customer and about how and by whom thatdescriptive information can be accessed and modified.

FIG. 18 illustrates an example computer system 1800 in which variousembodiments of the present invention may be implemented. The system 1800may be used to implement any of the computer systems described above. Asshown in the figure, computer system 1800 includes a processing unit1804 that communicates with a number of peripheral subsystems via a bussubsystem 1802. These peripheral subsystems may include a processingacceleration unit 1806, an I/O subsystem 1808, a storage subsystem 1818and a communications subsystem 1824. Storage subsystem 1818 includestangible computer-readable storage media 1822 and a system memory 1810.

Bus subsystem 1802 provides a mechanism for letting the variouscomponents and subsystems of computer system 1800 communicate with eachother as intended. Although bus subsystem 1802 is shown schematically asa single bus, alternative embodiments of the bus subsystem may utilizemultiple buses. Bus subsystem 1802 may be any of several types of busstructures including a memory bus or memory controller, a peripheralbus, and a local bus using any of a variety of bus architectures. Forexample, such architectures may include an Industry StandardArchitecture (ISA) bus, Micro Channel Architecture (MCA) bus, EnhancedISA (EISA) bus, Video Electronics Standards Association (VESA) localbus, and Peripheral Component Interconnect (PCI) bus, which can beimplemented as a Mezzanine bus manufactured to the IEEE P1386.1standard.

Processing unit 1804, which can be implemented as one or more integratedcircuits (e.g., a conventional microprocessor or microcontroller),controls the operation of computer system 1800. One or more processorsmay be included in processing unit 1804. These processors may includesingle core or multicore processors. In certain embodiments, processingunit 1804 may be implemented as one or more independent processing units1832 and/or 1834 with single or multicore processors included in eachprocessing unit. In other embodiments, processing unit 1804 may also beimplemented as a quad-core processing unit formed by integrating twodual-core processors into a single chip.

In various embodiments, processing unit 1804 can execute a variety ofprograms in response to program code and can maintain multipleconcurrently executing programs or processes. At any given time, some orall of the program code to be executed can be resident in processor(s)1804 and/or in storage subsystem 1818. Through suitable programming,processor(s) 1804 can provide various functionalities described above.Computer system 1800 may additionally include a processing accelerationunit 1806, which can include a digital signal processor (DSP), aspecial-purpose processor, and/or the like.

I/O subsystem 1808 may include user interface input devices and userinterface output devices. User interface input devices may include akeyboard, pointing devices such as a mouse or trackball, a touchpad ortouch screen incorporated into a display, a scroll wheel, a click wheel,a dial, a button, a switch, a keypad, audio input devices with voicecommand recognition systems, microphones, and other types of inputdevices. User interface input devices may include, for example, motionsensing and/or gesture recognition devices such as the Microsoft Kinect®motion sensor that enables users to control and interact with an inputdevice, such as the Microsoft Xbox® 360 game controller, through anatural user interface using gestures and spoken commands. Userinterface input devices may also include eye gesture recognition devicessuch as the Google Glass® blink detector that detects eye activity(e.g., ‘blinking’ while taking pictures and/or making a menu selection)from users and transforms the eye gestures as input into an input device(e.g., Google Glass®). Additionally, user interface input devices mayinclude voice recognition sensing devices that enable users to interactwith voice recognition systems (e.g., Siri® navigator), through voicecommands.

User interface input devices may also include, without limitation, threedimensional (3D) mice, joysticks or pointing sticks, gamepads andgraphic tablets, and audio/visual devices such as speakers, digitalcameras, digital camcorders, portable media players, webcams, imagescanners, fingerprint scanners, barcode reader 3D scanners, 3D printers,laser rangefinders, and eye gaze tracking devices. Additionally, userinterface input devices may include, for example, medical imaging inputdevices such as computed tomography, magnetic resonance imaging,position emission tomography, medical ultrasonography devices. Userinterface input devices may also include, for example, audio inputdevices such as MIDI keyboards, digital musical instruments and thelike.

User interface output devices may include a display subsystem, indicatorlights, or non-visual displays such as audio output devices, etc. Thedisplay subsystem may be a cathode ray tube (CRT), a flat-panel device,such as that using a liquid crystal display (LCD) or plasma display, aprojection device, a touch screen, and the like. In general, use of theterm “output device” is intended to include all possible types ofdevices and mechanisms for outputting information from computer system1800 to a user or other computer. For example, user interface outputdevices may include, without limitation, a variety of display devicesthat visually convey text, graphics and audio/video information such asmonitors, printers, speakers, headphones, automotive navigation systems,plotters, voice output devices, and modems.

Computer system 1800 may comprise a storage subsystem 1818 thatcomprises software elements, shown as being currently located within asystem memory 1810. System memory 1810 may store program instructionsthat are loadable and executable on processing unit 1804, as well asdata generated during the execution of these programs.

Depending on the configuration and type of computer system 1800, systemmemory 1810 may be volatile (such as random access memory (RAM)) and/ornon-volatile (such as read-only memory (ROM), flash memory, etc.) TheRAM typically contains data and/or program modules that are immediatelyaccessible to and/or presently being operated and executed by processingunit 1804. In some implementations, system memory 1810 may includemultiple different types of memory, such as static random access memory(SRAM) or dynamic random access memory (DRAM). In some implementations,a basic input/output system (BIOS), containing the basic routines thathelp to transfer information between elements within computer system1800, such as during start-up, may typically be stored in the ROM. Byway of example, and not limitation, system memory 1810 also illustratesapplication programs 1812, which may include client applications, Webbrowsers, mid-tier applications, relational database management systems(RDBMS), etc., program data 1814, and an operating system 1816. By wayof example, operating system 1816 may include various versions ofMicrosoft Windows®, Apple Macintosh®, and/or Linux operating systems, avariety of commercially-available UNIX® or UNIX-like operating systems(including without limitation the variety of GNU/Linux operatingsystems, the Google Chrome® OS, and the like) and/or mobile operatingsystems such as iOS, Windows® Phone, Android® OS, BlackBerry® 18 OS, andPalm® OS operating systems.

Storage subsystem 1818 may also provide a tangible computer-readablestorage medium for storing the basic programming and data constructsthat provide the functionality of some embodiments. Software (programs,code modules, instructions) that when executed by a processor providethe functionality described above may be stored in storage subsystem1818. These software modules or instructions may be executed byprocessing unit 1804. Storage subsystem 1818 may also provide arepository for storing data used in accordance with the presentinvention.

Storage subsystem 1800 may also include a computer-readable storagemedia reader 1820 that can further be connected to computer-readablestorage media 1822. Together and, optionally, in combination with systemmemory 1810, computer-readable storage media 1822 may comprehensivelyrepresent remote, local, fixed, and/or removable storage devices plusstorage media for temporarily and/or more permanently containing,storing, transmitting, and retrieving computer-readable information.

Computer-readable storage media 1822 containing code, or portions ofcode, can also include any appropriate media known or used in the art,including storage media and communication media, such as but not limitedto, volatile and non-volatile, removable and non-removable mediaimplemented in any method or technology for storage and/or transmissionof information. This can include tangible computer-readable storagemedia such as RAM, ROM, electronically erasable programmable ROM(EEPROM), flash memory or other memory technology, CD-ROM, digitalversatile disk (DVD), or other optical storage, magnetic cassettes,magnetic tape, magnetic disk storage or other magnetic storage devices,or other tangible computer readable media. This can also includenontangible computer-readable media, such as data signals, datatransmissions, or any other medium which can be used to transmit thedesired information and which can be accessed by computing system 1800.

By way of example, computer-readable storage media 1822 may include ahard disk drive that reads from or writes to non-removable, nonvolatilemagnetic media, a magnetic disk drive that reads from or writes to aremovable, nonvolatile magnetic disk, and an optical disk drive thatreads from or writes to a removable, nonvolatile optical disk such as aCD ROM, DVD, and Blu-Ray® disk, or other optical media.Computer-readable storage media 1822 may include, but is not limited to,Zip® drives, flash memory cards, universal serial bus (USB) flashdrives, secure digital (SD) cards, DVD disks, digital video tape, andthe like. Computer-readable storage media 1822 may also include,solid-state drives (SSD) based on non-volatile memory such asflash-memory based SSDs, enterprise flash drives, solid state ROM, andthe like, SSDs based on volatile memory such as solid state RAM, dynamicRAM, static RAM, DRAM-based SSDs, magnetoresistive RAM (MRAM) SSDs, andhybrid SSDs that use a combination of DRAM and flash memory based SSDs.The disk drives and their associated computer-readable media may providenon-volatile storage of computer-readable instructions, data structures,program modules, and other data for computer system 1800.

Communications subsystem 1824 provides an interface to other computersystems and networks. Communications subsystem 1824 serves as aninterface for receiving data from and transmitting data to other systemsfrom computer system 1800. For example, communications subsystem 1824may enable computer system 1800 to connect to one or more devices viathe Internet. In some embodiments communications subsystem 1824 caninclude radio frequency (RF) transceiver components for accessingwireless voice and/or data networks (e.g., using cellular telephonetechnology, advanced data network technology, such as 3G, 4G or EDGE(enhanced data rates for global evolution), WiFi (IEEE 1602.11 familystandards, or other mobile communication technologies, or anycombination thereof), global positioning system (GPS) receivercomponents, and/or other components. In some embodiments communicationssubsystem 1824 can provide wired network connectivity (e.g., Ethernet)in addition to or instead of a wireless interface.

In some embodiments, communications subsystem 1824 may also receiveinput communication in the form of structured and/or unstructured datafeeds 1826, event streams 1828, event updates 1830, and the like onbehalf of one or more users who may use computer system 1800.

By way of example, communications subsystem 1824 may be configured toreceive data feeds 1826 in real-time from users of social networksand/or other communication services such as Twitter® feeds, Facebook®updates, web feeds such as Rich Site Summary (RSS) feeds, and/orreal-time updates from one or more third party information sources.

Additionally, communications subsystem 1824 may also be configured toreceive data in the form of continuous data streams, which may includeevent streams 1828 of real-time events and/or event updates 1830, whichmay be continuous or unbounded in nature with no explicit end. Examplesof applications that generate continuous data may include, for example,sensor data applications, financial tickers, network performancemeasuring tools (e.g. network monitoring and traffic managementapplications), clickstream analysis tools, automobile trafficmonitoring, and the like. Communications subsystem 1824 may also beconfigured to output the structured and/or unstructured data feeds 1826,event streams 1828, event updates 1830, and the like to one or moredatabases that may be in communication with one or more streaming datasource computers coupled to computer system 1800.

Computer system 1800 can be one of various types, including a handheldportable device (e.g., an iPhone® cellular phone, an iPad® computingtablet, a PDA), a wearable device (e.g., a Google Glass® head mounteddisplay), a PC, a workstation, a mainframe, a kiosk, a server rack, orany other data processing system.

Due to the ever-changing nature of computers and networks, thedescription of computer system 1800 depicted in the figure is intendedonly as a specific example. Many other configurations having more orfewer components than the system depicted in the figure are possible.For example, customized hardware might also be used and/or particularelements might be implemented in hardware, firmware, software (includingapplets), or a combination. Further, connection to other computingdevices, such as network input/output devices, may be employed. Based onthe disclosure and teachings provided herein, a person of ordinary skillin the art will appreciate other ways and/or methods to implement thevarious embodiments.

In the foregoing specification, aspects of the invention are describedwith reference to specific embodiments thereof, but those skilled in theart will recognize that the invention is not limited thereto. Variousfeatures and aspects of the above-described invention may be usedindividually or jointly. Further, embodiments can be utilized in anynumber of environments and applications beyond those described hereinwithout departing from the broader spirit and scope of thespecification. The specification and drawings are, accordingly, to beregarded as illustrative rather than restrictive.

What is claimed is:
 1. A computer-implemented method comprising:receiving, at an OAuth authorization server, from a first applicationexecuting on a first mobile device, a first registration request foraccess by multiple applications on the first mobile device, wherein thefirst registration request includes a first device token that ispreviously received by the first application from a server computer thatprovides a service, wherein the first device token includes an identityof the first application that the service uses to identify the firstapplication, and wherein the server computer is different from the OAuthauthorization server; in response to receiving the first registrationrequest, the OAuth authorization server generating a first clientregistration token for the first application; splitting the first clientregistration token into a first part and a second part; encrypting thefirst part of the first client registration token and the second part ofthe first client registration token; sending, from the OAuthauthorization server, to the server computer that provides the service,the first device token and a notification specifying the first part ofthe first client registration token; and sending, from the OAuthauthorization server, the second part of the first client registrationtoken to the first mobile device through a communication channel that isunrelated to the service.
 2. The computer-implemented method of claim 1,wherein the service is an Apple Push Notification Service (APNS);wherein the first application received the first device token from theAPNS as part of a registration process in which the first applicationengaged with the APNS; and wherein the APNS uses the first device tokento push notifications to the first application.
 3. Thecomputer-implemented method of claim 1, wherein the service is a GoogleCloud Messaging (GCM) service, and wherein the first applicationreceived the first device token from the GCM service as part of aregistration process in which the first application engaged with the GCMservice; and wherein the GCM service uses the first device token to sendmessages to the first application.
 4. The computer-implemented method ofclaim 1, wherein the communication channel is a Hypertext TransferProtocol (HTTP) channel through which the OAuth authorization serverreceived the first registration request from the first mobile device. 5.The computer-implemented method of claim 1, further comprising:receiving, at an OAuth authorization server, from a second applicationexecuting on a second mobile device, a second registration request foraccess by multiple applications on the second mobile device, wherein thesecond registration request includes a second device token that ispreviously received by the second application from a server computerthat provides a service, wherein the second device token includes anidentity of the second application that the service uses to identify thesecond application, and wherein the server computer is different fromthe OAuth authorization server; in response to receiving the secondregistration request, the OAuth authorization server generating a secondclient registration token for the first application; splitting thesecond client registration token into a first part and a second part;encrypting the first part of the second client registration token andthe second part of the second client registration token; sending, fromthe OAuth authorization server, to the server computer that provides theservice, the second device token and a notification specifying the firstpart of the second client registration token; and sending, from theOAuth authorization server, the second part of the second clientregistration token to the second mobile device through a communicationchannel that is unrelated to the service; wherein the second devicetoken differs from the first device token.
 6. A non-transitorycomputer-readable storage media comprising instructions which, whenexecuted by one or more processors, cause the one or more processors toperform: receiving, at an OAuth authorization server, from a firstapplication executing on a first mobile device, a first registrationrequest for access by multiple applications on the first mobile device,wherein the first registration request includes a first device tokenthat is previously received by the first application from a servercomputer that provides a service, wherein the first device tokenincludes an identity of the first application that the service uses toidentify the first application, and wherein the server computer isdifferent from the OAuth authorization server; in response to receivingthe first registration request, the OAuth authorization servergenerating a first client registration token for the first application;splitting the first client registration token into a first part and asecond part; encrypting the first part of the first client registrationtoken and the second part of the first client registration token;sending, from the OAuth authorization server, to the server computerthat provides the service, the first device token and a notificationspecifying the first part of the first client registration token; andsending, from the OAuth authorization server, the second part of thefirst client registration token to the first mobile device through acommunication channel that is unrelated to the service.
 7. Thenon-transitory computer-readable storage media of claim 6, wherein theservice is an Apple Push Notification Service (APNS); wherein the firstapplication received the first device token from the APNS as part of aregistration process in which the first application engaged with theAPNS; and wherein the APNS uses the first device token to pushnotifications to the first application.
 8. The non-transitorycomputer-readable storage media of claim 6, wherein the service is aGoogle Cloud Messaging (GCM) service, and wherein the first applicationreceived the first device token from the GCM service as part of aregistration process in which the first application engaged with the GCMservice; and wherein the GCM service uses the first device token to sendmessages to the first application.
 9. The non-transitorycomputer-readable storage media of claim 6, wherein the communicationchannel is a Hypertext Transfer Protocol (HTTP) channel through whichthe OAuth authorization server received the first registration requestfrom the first mobile device.
 10. The non-transitory computer-readablestorage media of claim 6, further comprising: receiving, at the OAuthauthorization server, from a second application executing on a secondmobile device, a second registration request that includes a seconddevice token that is previously received by the second application froma server computer that provides the service, wherein the second devicetoken includes an identity of the second application that the serviceuses to identify the second application; in response to receiving thesecond registration request, the OAuth authorization server generating asecond client registration token for the second application; splittingthe second client registration token into a first part and a secondpart; and sending, from the OAuth authorization server, the seconddevice token and the first part of the second client registration tokento server computer that provides the service; wherein the second devicetoken differs from the first device token.
 11. A system comprising: afirst mobile device that stores a first application; and a machine thatis separate from the first mobile device and that stores an OAuthauthorization server that is configured to: receive, from the firstapplication, a first registration request for access by multipleapplications on the first mobile device, wherein the first registrationrequest includes a first device token that is previously received by thefirst application from a server computer that provides a service,wherein the first device token includes an identity of the firstapplication that the service uses to identify the first application, andwherein the server computer is different from the OAuth authorizationserver; generate a first client registration token for the firstapplication in response to receiving the first registration request;split the first client registration token into a first part and a secondpart; encrypt the first part of the first client registration token andthe second part of the first client registration token; send to theserver computer that provides the service, the first device token and anotification specifying the first part of the first client registrationtoken; and send the second part of the first client registration tokento the first mobile device through a communication channel that isunrelated to the service.
 12. The system of claim 11, wherein theservice is an Apple Push Notification Service (APNS); wherein the firstapplication received the first device token from the APNS as part of aregistration process in which the first application engaged with theAPNS; and wherein the APNS uses the first device token to pushnotifications to the first application.
 13. The system of claim 11,wherein the service is a Google Cloud Messaging (GCM) service, andwherein the first application received the first device token from theGCM service as part of a registration process in which the firstapplication engaged with the GCM service; and wherein the GCM serviceuses the first device token to send messages to the first application.14. The system of claim 11, wherein the communication channel is aHypertext Transfer Protocol (HTTP) channel through which the OAuthauthorization server received the first registration request from thefirst mobile device.
 15. The system of claim 11, further comprising: asecond mobile device that stores a second application and that isseparate from the first mobile device; and wherein the OAuthauthorization server is configured to: receive, from the secondapplication, a second registration request that includes a second devicetoken that is previously received by the second application from aserver computer that provides the service, wherein the second devicetoken includes an identity of the second application that the serviceuses to identify the first application; generate a second clientregistration token for the second application in response to receivingthe second registration request; split the second client registrationtoken into a first part and a second part; encrypt the first part of thesecond client registration token and the second part of the secondclient registration token; send, to the server computer that providesthe service, the second device token and a notification specifying thesecond client registration token; and send the second part of the secondclient registration token to the second mobile device through acommunication channel that is unrelated to the service; wherein thesecond device token differs from the first device token.